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Back matter |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 015-016
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JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991 VOL. 6 xvii Alan Date Memorial Award 1991 In recognition of the considerable contribution made by Dr Alan Date to the field of inductively coupled plasma source mass spectrometry an annual commemorative award has been created to encourage talented young scientists to broaden their overseas scientific experience. Candidates should be working in the field of atmospheric pressure plasma source mass spectrometry (inorganic) and will be required to submit a written resume of their work in this field. It is intended that this may form the basis of a publication. An amount of up to %lo00 will be available to the successful candidate@) Closing date for submissions will be October 26th 1991. Further details of the award may be obtained from Dr Robert Hutton VG Elemental Ion Path Road Three Winsford Cheshire CW7 3BX UK.JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUG'S 1 READER ENQUIRY SERVICE For further information about any of the productsfeatured in the advertisements in this issue please write the appropriate number in one of the boxes below.Postage paid if posted in the British Isles but overseas readers must affix a stamp. L PLEASE USE BLOCK CAPITALS LEAVING A SPACE BETWEEN WORDS Valid 12 monrh I I I T - _ - . ' NAME \ t ~lil 1 I I I r I I I I I I r ~ i I I I 1 I I I I - I I 1 1 l l I l I I I I I I I ~ I " ~ ~ I I I 1 I L Z 2 COMPANY PLEASE GIVE YOUR BUSINESS ADDRESS IF POSSIBLE. IF NOT PLEASE TICK HERE [= c 3 STREET 1 I 1 i I 1 1 I I 1 I i I I i i I I 1 1 i ; 11-11LII I 4 TOWN I i 1 l I l I I l I T I T T I 1 I I i 1 I i l ; I ! I I l l I I ' I I I I i I 1 1 l 1 - 1 1 i - i i i i I i I l l I l l T i 1 I I I I 1 1 1 1 I I 1 .1 1 1 1 i 1 1 1 1 1 1 - I I I I I 1 5 COUNTY POST LODE 6 COUNTRY 7- 7 DEPARTMENT DIVISION 8 YOUR JOB TITLE POS IT1 ON I I I I i 1 I I ! 1 1 I I I I I i I I I - L L U L 9 TELEPHONE NO I - OFFICE USE ONLY K E L L ) PHOC I ) - FOLD HERE I Postage will be paid by Licensee Do not affix Postage Stamps if posted in Gt. Britain Channdl Islands N. Ireland or the Isle of Man BUSINESS REPLY SERVICE Reader Enquiry Service Journal of Analytical Atomic Spectrometry The Royal Society of Chemistry Burlington House Piccadilly LONDON WIE 6WF England I I 2 .- I I 1 I I I I I I I I I I I r I I I I I I I I I I I I I 1 I 1 I I I I 1 I I I I I I I I I I I ! - 1 I I I I I I I b 1 1 I I I I I 1 I I I I I I I I t I I I I I I I I 1 I I I I I I I I I I I I I I I I I I I I I I I 1 I I I I I I I I I I i I I I I I I I I I I 1 I I I I I I I I I I I I I t I I I I I 1 I h I I I I I I I I I 1 t 1 I I I I I I I I I I I I I t I I I I I I I I I I I I I I i I I I I I I I I i I I I I I I I I I I I I I I I I I I I I I I I I I I \ I I
ISSN:0267-9477
DOI:10.1039/JA99106BP015
出版商:RSC
年代:1991
数据来源: RSC
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Front cover |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 017-018
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Journal of Analytical Atomic Spectrometry (Including Atomic Spectrometry Updates) JAAS Editorial Board* Chairman L Ebdon (Plymouth UK) J Egan (Cambrldge UK) D A Hickman (London UK) B L Sharp (Loughborough UK) J Marshall (Middlesbrough UK) J M Mermet (Vdleurbanne France) D. L Miles (Keyworth UK) R D Snook (Manchester UK) "The JAAS Editorial Board reports to the Analytical Editorial Board Chairman A G Fogg (Loughborough UK) JAAS Advisory Board F C Adams (Antwerp Belg/um) R M Barnes (Amherst MA USA) L Bezur (Budapest Hungary) R F Browner (Atlanta GA USA) S Caroli (Rome Italy) A J Curtius (R/o de Janeiro Braz4 L de Galan (Vlaardingen The Nethei J B Dawson (Leeds UK) K Dittrich (Leqmg Germany) W Frech (Umea Sweden) K Fuwa (Tokyo Japan) A L Gray (Egham UKI S Greenfield (Loughborough UK) G M Hieftje (Bloomlngton IN USA) G Horlick (Edmonton Canada) B V L'vov (Lenmgrad USSR) Ni Zhe-ming (Belling Chma) N Omenetto (lspra Italy) .lands) T C Rains (Charleston SC USA) R E Sturgeon (Ottawa Canada) R Van Grieken (Antwerp Belgium) A Walsh K B (Victoria Australla) B Welz (Uberlingen FRG) T S West (Aberdeen UIO Atomic Spectrometry Updates Editorial Board Chairman "D L Miles (Keyworth UK) J Armstrong (Dumfries UK) "J Marshall (Middlesbrough UK) J R Bacon (Aberdeen UK) H Matusiewicz (Poznan Poland C Barnard (Glasgow UK) J M Mermet (Vdleurbanne France) R M Barnes (Amherst MA USA) R G Michel (Storrs CT USA) S Branch IMgh Wycombe UK) T Nakahara (Osaka Japan) R Bye (Oslo Norway) NI Zhe-ming (Beyng China) J Carroll (Middlesbrough UK) P R Poole (Hamilton New Zealand) M R Cave (Keyworth UK) W J Price (Ashburton UK) *J M Cook (Keyworth UK) C J Rademeyer (Pretoria South Africa) "M S Cresser (Aberdeen UK) M H Ramsey (London UM H M Crews (Norwich UK) A Sanz-Medel (Oviedo Spain) J S Crighton (Sunbury-on-Thames UK) I L Shuttler (Uberlinger; FRG) "J B Dawson (Leeds UK) S T Sparkes (Plymouth UK) J R Dean (Newcastle upon Tyne UM R Stephens (Hallfax Canada) "L Ebdon (Plymouth UK) J Stupar (Llubhana Yugoslavia) "J Egan (Cambridge UK) R E Sturgeon (Ottawa Canadd "A T Ellis (Oxford UK) A Taylor (Guildford UKI "D J Halls (Glasgow UK) G C Turk (Gaithersburg MD USA) *D A Hickman (London UK) J F Tyson (Amherst MA USA) " S J Hill (Plymouth UK) *A M Ure (Aberdeen UK) K W Jackson (Albany NY USA) S J Walton (Crawley UK) R Jowitt (Middlesbrough UM P Watkins (London UK) K Kitagawa (Nagoya Japan) B Welz (Uberlingen FRG) J Kubova (Bratislava Czechoslovakia) J Williams (Egham UK) J B Willis (Victorla Australla) J Fazakas (Bucharest Romania) A P Thorne(London UK) "D Littlejohn (Glasgow UK) "Members of the ASU Executive Committee Editor JAAS Jcldith Egan The Royal Society of Chemistry Dr J M Harnly Thomas Graham House Science Park Milton Road Cambridge CB4 4WF UK Telex No 81 8293 Fax 0223 423623 Assistant Editors Brenda Holliday Edmrial Secretary Mon iqu e Warner US Associate Editor JAAS US Department of Agriculture Beltsville Human Nutriton Research Center Beltsville MD 20705 USA Telephone 301 -344-2569 Telephone 0223 420066 BLDG 161 BARC-EAST Paula O'Riordan Sheryl Whitewood ~ Advertisements Advertisement Department The Royal Society of Chemistry Burlington House Piccadilly London W1V OBN UK. Telephone 071-437 8656 Fax 071-437 8883 Information for Authors Full details of how to submit materials for publica- tion in JAAS are given in the Instructions to Authors in Issue 1 Separate copies are available on request.The Journal of Analytcal Atornx Spectrometry (JAAS) is an international journal for the publica- tion of original research papers communications and letters concerned with the development and analytical application of atomic spectrometric techniques The journal is published eight times a year including comprehensive reviews of specific topics of interest to practising atomic spectrosco- pists and incorporates the literature reviews which were previously published in Annual Reports on Analytical Atomic Spectroscopy (ARAAS) Manuscripts intended for publication must de- scribe original work related to atomic spectromet- ric analysis Papers on all aspects of the subject will be accepted including fundamental studies novel instrument developments and practical ana- lytical applications As well as AAS AES and AFS papers will be welcomed on atomic mass spectro- metry and X-ray fluorescence/emission spectro- metry Papers describing the measurement of molecular species where these relate to the char- acterization of sources normally used for the pro- duction of atoms or are concerned for example with indirect methods of analysis will also be ac- ceptable for publication Papers describing the de- velopment and applications of hybrid techniques (e g GC-coupled AAS and HPLC-ICP) will be par- ticularly welcome Manuscripts on other subjects of direct interest to atomic spectroscopists in- cluding sample preparation and dissolution and analyte pre-concentration procedures as well as the statistical interpretation and use of atomic spectrometric data will also be acceptable for pub- lication There is no page charge The following types of papers will be consid- ered Full papers describing original work Communications which must be on an urgent matter and be of obvious scientific importance Communications receive priority and are usually published within 2-3 months of receipt They are intended for brief descriptions of work that has progressed to a stage at which it is likely to be valuable to workers faced with similar problems Reviews which must be a critical evaluation of the existing state of knowledge on a particular facet of analytical atomic spectrometry Every paper (except Communications) will be submitted to at least two referees by whose advice the Editorial Board of JAAS will be guided as to its acceptance or rejection Papers that are accepted must not be published elsewhere except by permission Submission of a manu- script will be regarded as an undertaking that the same material is not being considered for publica- tion by another journal Manuscripts (three copies typed in double spacing) should be sent to Judith Egan. Editor.JAAS or Dr J M Harnly US Associate Editor JAA S All queries relating to the presentation and sub- mission of papers and any correspondence re- garding accepted papers and proofs should be directed to the Editor or US Editor (addresses as above) Members of the JAAS Editorial Board (who may be contacted directly or via the Editorial Office) would welcome comments suggestions and advice on general policy matters concerning JAAS Fifty reprints are supplied free of charge Journal of Analytical Atomic Spectrometry (JAAS) (ISSN 0267-9477) IS published eight times a year by The Royal Society of Chemistry Thomas Graham House Science Park Milton Road Cambridge CB4 4WF UK All orders accompanied with payment should be sent directly to The Royal Society of Chemistry Turpin Tractions Ltd Blackhorse Road Letchworth Herts SG6 1 HN UK Tel +44 (0) 462 672555 Telex 825372 Turpin G Fax +44 (0) 462 480947 Turpin Transactions Ltd is wholly owned by The Royal Society of Chemistry 1991 Annual subscription rate EC €309 00 USA $728 00 Rest of World €355 00 Customers should make payments by cheque in sterling payable on a UK clearing bank or in US dollars payable on a US clearing bank Air freight and mailing in the USA by Publications Expediting Inc 200 Meacham Avenue Elmont NY 11003 USA Postmaster send address changes to Journal of Analytical Atomic Spectrometry (JAAS) Publications Expediting Inc 200 Meacham Avenue Elmont NY 11003 Second class postage paid at Jamaica NY 11431 All other despatches outside the UK by Bulk Airmail within Europe Accelerated Surface Post outside Europe PRINTED IN THE UK 0 The Royal Society of Chemistry 1991 All rights reserved No part of this publication may be reproduced stored in a retrieval system or transmitted in any form or by any means electronic mechanical photographic recording or otherwise without the prior permission of the publishersJournal of Analytical Atomic Spectrometry (Including Atomic Spectrometry Updates) JAAS Editorial Board* Chairman L.Ebdon (Plymouth UK) J Egan (Cambridge UK) D L Miles (Keyworth UK) D A Hickman (London UK? B L Sharp (Loughborough UK? J Marshall (Middlesbrough UK) R D Snook(Manchestei UK) J M Mermet (Vdleurbanne France) *The JAAS Editorial Board reports to the Analytical Editorial Board Chairman A G Fogg (Loughborough UK) JAAS Advisory Board F C Adams (Antwerp Belgium) R M Barnes (Amherst MA USA) G M Hieftje (Bloomington IN USA) L Bezur (Budapest Hungary) R F Browner (Atlanta GA USA) S Caroli (Rome Italy) A J Curtius (Rio de Janeiro Brazil) L de Galan (Vlaardmgen The Netherlands) J B Dawson (Leeds UK) R E Sturgeon (Ottawa Canada) K Dittrich (Leipng Germany) W Frech (UmeS Sweden) A Walsh K B (Victoria Australia) K Fuwa (Tokyo Japan) B Welz (Uberlingen FRG) A L Gray (Egham UM T S West (Aberdeen UM S Greenfield (Loughborcugh UK) G Horlick (Edmonton Canada) B V L'vov (Leningrad USSR) Ni Zhe-ming (Beiling China) N Omenetto (lspra Italy) T C Rains (Charleston SC USA) R Van Grieken (Antwerp Belgium) Atomic Spectrometry Updates Editorial Board Chairman *D L J Armstrong (Dumfnes UM J R Bacon (Aberdeen UK? C Barnard (Glasgow UK) R M Barnes (Amherst MA USA) S Branch (High Wycombe UK) R Bye (Oslo Norway) J Carroll (Middlesbrough UK) M R Cave (Keyworth UK) "J M Cook (Keyworth UK) "M S Cresser (Aberdeen UK) H M Crews (Norwich UK) J S Crighton (Sunbury-on-Thames UK) J R Dean (Newcastle upon Tyne UK) "J B Dawson (Leeds UKI " L Ebdon (Plymouth UK) *J Egan (Cambridge UK) "A T Ellis (Oxford UK) *D J Halls (Glasgow UK) "D A Hickman (London UK) * S J Hill (Plymouth UK) J Fazakas (Bucharest Romania) K W Jackson (Albany NY USA) R Jowitt (Middlesbrough UK) K Kitagawa (Nagoya Japan) J Kubova (Bratislava Czechoslovakia) "D Littlejohn (Glasgow UK) Miles (Keyworth UK) "J Marshall (Middlesbrough UK) H Matusiewicz (Poznan Poland) J M Mermet (Villeurbanne France) R G Michel (Storrs CT USA) T Nakahara (Osaka Japan) Ni Zhe-ming (Beying China) P R Poole (Hamilton New Zealand W J Price (Ashburton UK) C J Rademeyer (Pretoria South Afr/ca) M H Ramsey(London UK) A Sanz-Medel (Ovredo Spain) I L Shuttler (Uberlmgen FRG) S T SparKes (Plymouth UK) R Stephens (Halifax Cmada) J Stupar (Llubhana Yugoslavia) R E Sturgeon (Ottawa Canada) A Taylor (Guildford UKi A P Thorne (London LIM G C Turk (Gaithersburg MD USA) J F Tyson (Amherst MA USA) *A M Ure (Aberdeen UK) S J Walton (Crawley OK) P Watkins (London Uk) B Welz (Uberlingen FF'G) J Williams (Egham UKi J B Willis (Victorm Au.;tralia) *Members of the ASU Executive Committee ~ ~ ~ ~~ ~ Editor JAAS Judith Egan The Royal Society of Chemistry Dr J M Harnly Thomas Graham House Science Park Milton Road Cambridge CB4 4WF UK Telex No 81 8293 Fax 0223 423623 Assistant Editors Brenda Holliday Editorial Secretary Monique Warner US Associate Editor JAAS US Department of Agriculture Beltsville Human Nutriton Research Center Beltsville MD 20705 USA Telephone 30 1 -344-2 569 Telephone 0223 420066 BLDG 161 BARC-EAST Paula O'Riordan Sheryl Whitewood Advertisements Advertisement Department The Royal Society of Chemistry Burlington House Piccadilly London W I V OBN UK.Telephone 071-437 8656. Fax 071-437 8883 Information for Authors Full details of how to submit materials for publica- tion in JAAS are given in the Instructions to Authors in Issue 1 Separate copies are available on request The Journal of Analytical Atomic Spectrometry (JAA.9 is an international journal for the publica- tion of original research papers communications and letters concerned with the development and analytical application of atomic spectrometric techniques The journal is published eight times a year including comprehensive reviews of specific topics of interest to practising atomic spectrosco- pists and incorporates the literature reviews which were previously published in Annual Reports on Analytical Atomic Spectroscopy (ARAAS) Manuscripts intended for publication must de- scribe original work related to atomic spectromet- ric analysis Papers on all aspects of the subject will be accepted including fundamental studies novel instrument developments and practical ana- lytical applications As well as AAS AES and AFS papers will be welcomed on atomic mass spectro- metry and X-ray fluorescence/emission spectro- metry Papers describing the measurement of molecular species where these relate to the char- acterization of sources normally used for the pro- duction of atoms or are concerned for example with indirect methods of analysis will also be ac- ceptable for publication Papers describing the de- velopment and applications of hybrid techniques ( e g GC-coupled AAS and HPLC-ICP) will be par- ticularly welcome Manuscripts on other subjects of direct interest to atomic spectroscopists in- cluding sample preparation and dissolution and analyte pre-concentration procedures as well as the statistical interpretation and use of atomic spectrometric data will also be acceptable for pub- lication There is no page charge The following types of papers will be consid- ered Full papers describing original work Comrnunicatmx which must be on an urgent matter and be of obvious scientific importance Communications receive priority and are usually published within 2-3 months of receipt They are intended for brief descriptions of work that has progressed to a stage a t which it is likely to be valuable to workers faced with similar problems Reviews which must be a critical evaluation of the existing state of knowledge on a particular facet of analytical atomic spectrometry Every paper (except Communications) will be submitted to at least two referees by whose advice the Editorial Board of JAAS will be guided as to its acceptance or rejection Papers that are accepted must not be published elsewhere except by permission Submission of a mancr- script will be regarded as an undertaking that the same material is not being considered for publica- tion by another journal Manuscripts (three copies typed in double spacing) should be sent to Judith Egan Editor.JAAS or Dr J M Harnly US Associate Editor JAAS All queries relating to the presentation and sub- mission of papers and any correspondence re- garding accepted papers and proofs should be directed to the Editor or US Editor (addresses as above) Members of the JAAS Editorial Board (who may be contacted directly or via the Editorial Office) would welcome comments suggestions and advice on general policy matters concerning JAAS ~ ~ Fifty reprints are supplied free of charge. Journal of Analytical Atomic Spectrometry (JAAS) (ISSN 0267-9477) is published eight times a year by The Royal Society of Chemistry Thomas Graham House Science Park Milton Road Cambridge CB4 4WF UK.All orders accompanied with payment should be sent directly to The Royal Society of Chemistry Turpin Tractions Ltd. Blackhorse Road Letchworth Herts. SG6 1 HN UK Tel. +44 (0) 462 672555; Telex 825372 Turpin G; Fax +44 (0) 462 480947. Turpin Transactions Ltd. is wholly owned by The Royal Society of Chemistry. 1991 Annual subscription rate EC €309.00 USA $728.00 Rest of World €355.00. Customers should make payments by cheque in sterling payable on a UK clearing bank or in US dollars payable on a US clearing bank. Air freight and mailing in the USA by Publications Expediting Inc. 200 Meacham Avenue Elmont NY 11003. USA Postmaster send address changes to Journal of Analytical Atomic Spectrometry (JAASI Publications Expediting Inc. 200 Meacham Avenue Elmont NY 11 003. Second class postage paid at Jamaica NY 11431. All other despatches outside the UK by Bulk Airmail within Europe Accelera?ed Surface Post outside Europe. PRINTED IN THE UK. 0 The Royal Society of Chemistry 1991. All rights reserved. No part of this publication may be reproduced stored in a retrieval system or transmitted in any form or by any means electronic mechanical photographic recording or otherwise without the prior permission of the publishers.
ISSN:0267-9477
DOI:10.1039/JA99106FX017
出版商:RSC
年代:1991
数据来源: RSC
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Contents pages |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 019-020
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JASPE2 6(4) 345-404 187R-228R { 1991) August 1991 Journal of Analytical Atomic Spectrometry I ncl u d in g Atomic S pect rorn e t ry c1 pd a t es CONTENTS NEWS AND VIEWS 345 348 Book Review-J. R Bacon 349 Conferences and Meetings 352 Papers in Future Issues Conference Reports-Julian F Tyson and Simon Branch PAPERS 353 375 379 385 389 393 397 403 Solid Sampling in Electrothermal Atomic Absorption Spectrometry Using Commercial Atomizers. A Review-Carlos Bendicho Margaretha T C de Loos- Vollebregt Electrothermal Atomic Absorption spectrometry of Inorganic and Organic Arsenic Species Using Conventional and Fast Furnace Programmes-Erik H Larsen Comparison of Dry Mineralization and Microwave-oven Digestion for the Determination of Arsenic in Mussel Products by Platform in Furnace Zeeman- effect Atomic Absorption Spectrometry-N Ybafiez M L Cervera R Montoro Miguel de la Guardia Determination of Tributyltin and Inorganic Tin in Sea-water by Solvent Extraction and Hydride Generation Electrothermal Atomic Absorption Spectrometry-Ni Zhe- ming Hang Heng-bin LI Ang He Bin Xu Fu-zheng Hydride Generation Atomic Absorption Spectrometry From Alkaline Solutions Determination of Selenium in Copper and Nickel Materials-Torild Wickstrom Walter Lund Ragnar Bye Characterization of Automotive Catalysts Using Inductively Coupled Plasma Mass Spectrometry Sample Preparation-James A Brown Jr Frank W Kunz Ronald K Belitz Direct Analysis of Slags by Inductively Coupled Plasma Atomic Emission Spectrometry Using Slurry Sample Introduction Techniques-Maria Luisa Fernandez Sanchez Ben Fairman Alfred0 Sanz-Medel CUMULATIVE AUTHOR INDEX ATOMIC SPECTROMETRY 187R Advances in Atomic Absorption and Fluorescence and Related Techniques-Steve UPDATE J.Hill John B. Dawson LV John Price Ian L Shuttler Julian F Tyson 221 R References i Preliminary Programme 1 992 Winter Conference on Plasma SpectrochemistrySTANDARD TYPE 1 ROYAL SOClETY OF To Order Please write to the Royal Society of chemistry Turpin Transactions Ltd Blackhorse Road Letchworth Herts SG6 1 HN UK. or telephone (0462) 672555 quoting your credit card details. We can now accept AccessNisa/MasterCard/Eurocard. S. &. J. JUNIPER & C 7 Potter Street Harlow Essex. Tel 0. 0279 4Q2456 Circle 001 for further information ROYAL SOCIETY OF CHEMISTRY The COSHH Regulations A Practical Guide - Edited by D.Simpson and W. G. Simpson Principal Consultants Analysis for Industry The COSHH (Control of Substances Hazardous to Health) Regulations are the most significant health and safety legislation since the Health and Safety at Work Act 1974. Chemists are one of the largest professional groups to be affected by these regulations and this new book provides a definitive guide to their implications and implementation. The Regulations apply to employers in every walk of life as well as to the self-employed and The COSHH Regulations A Practical Guide warns of the penalties that will follow any harm to employees or the general public. It offers realistic help and advice on the steps to be taken to comply with the Regulations or prepare a defence if necessary. Based on the editors’ and contributors’ wide experience the book is immensely practical and provides examples of the application of the Regulations in many different fields of business and commercial life. It is one of the few independent publications available on the COSHH Regulations and is an essential addition to the bookshelf of anyone with an interest in or responsibility for safety. Hardcover Approx 208 pages 234 x 156 mm Price f45.00 ISBN 0 85186 189 X Autumn 1991 Circle 002 for further information
ISSN:0267-9477
DOI:10.1039/JA99106BX019
出版商:RSC
年代:1991
数据来源: RSC
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Atomic Spectrometry Update—Advances in Atomic Absorption and Fluorescence Spectrometry and Related Techniques |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 187-220
Steve J. Hill,
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JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRYy AUGUST 1 99 1 VOL. 6 187R ATOMIC SPECTROMETRY UPDATE-ADVANCES IN ATOMIC ABSORPTION ANDFLUORESCENCESPECTROMETRYAND RELATEDTECHNIQUES Steve J. Hill" Department of Environmental Sciences Polytechnic South West Plymouth Devon PL4 8AA UK John 6. Dawson Department of Instrumentation and Analytical Science UMIST P. 0. Box 88 Manchester M60 1 QO UK W. John Price 75 Amberley Close Holne Cross Ashburton Devon UK Ian L. Shuttler Bodenseewerk Perkin-Elmer GmbH Postfach 101 764 0-7770 Uberlingen Germany Julian F. Tyson Department of Chemistry University of Massachusetts Amherst MA 01 003-0035 USA Summary of Contents 1 Atomic Absorption Spectrometry 1 .l. Flame Atomizers 1.1 .l. Fundamental studies 1.1.2. Interference studies 1.1.3. Sample introduction 1.1.3.1.Discrete procedures 1.1.3.2. Atom-trapping techniques 1.1.3.4. Sample introduction by flow injection 1.1.3.5. Solid sample introduction 1.1.4. Chromatographic detection 1.2. Electrothermal Atomizers 1.2.1. Atomizer design and surface modification 1.2.2. Sample introduction 1.2.3. Fundamental processes 1.2.4. Interferences 1.2.5. Developments in technique 1.3. Chemical Vapour Generation 1.3.1. Hydride generation 1.3.2. Preparation-separation of volatile organometallic compounds for chemical vapour AAS 1.3.3. Mercury by cold vapour generation 1.4.1. Light sources 1.4.2. Optics 1.4.3. Detectors 1.4.4. Background correction 1.4.5. Continuum source and simultaneous multi-element AAS 1.5.1. Instrument control 1.5.2. Data processing 1.5.3. Chemometrics 1.4. Spectrometers 1.5.Instrument Control and Data Processing 2 Atomic Fluorescence Spectrometry 2.1. Discharge Lamp Excited Atomic Fluorescence 2.2. Laser-excited Atomic Fluorescence Spectrometry 2.2.1. Electrothermal atomization 2.2.2. Low pressure atomization systems 2.3. Inductively Coupled Plasma Excited Atomic Fluorescence 2.4. Studies of Flames and Plasmas Using Laser-induced Fluorescence 3 Laser-enhanced Ionization 3.1. Systems Operating at Atmospheric Pressure 3.2. Systems Operating at Reduced Pressure 4 Atomic Magneto-optical Rotation Spectrometry * Review Co-ordinator to whom correspondence should be addressed.188R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 In previous years the third and fourth ASU reviews in JAAS have been devoted to ‘Instrumentation’ and ‘Atomization and Excitation’ covering developments in equipment-procedures and fundamental processes respectively.Many of the advances in analytical atomic spectrometry reported in the ASU references concern research in both of these areas and duplication of coverage was becoming difficult to avoid. As a separate ASU deals with all aspects of XRF and atomic mass spectrometry it has been decided to create two new reviews on ‘Atomic Emission Spectrometry’ and ‘Atomic Absorption Spectrometry Atomic Fluorescence Spectrometry and Related Techniques’. The review on ‘Atomic Emission Spectrome- try’ may be found in JAAS Volume 6 Issue 4. The present review describes developments in all aspects of atomic absorption spectrometry atomic fluorescence spectrometry and related techniques including fundamental processes and instrumentation reported in the Atomic Spectrometry Updates References in JAAS Volume 5 (90/1159-90/4179) and Volume 6 (91/1-91/2702).The full references names and addresses of authors can be readily found from the Atomic Spectrometry Update References in the relevant issues of JAAS. However as an additional service to readers an abbreviated form of each literature reference quoted (except for those to Conference Abstracts) is given at the end of the review. Comments on the new format of the reviews are welcome. 1. ATOMIC ABSORPTION SPECTROMETRY 1.1. Flame Atomizers 1.1.1. Fundamental studies The relatively few publications that have appeared during this review period concerned with fundamental studies of processes in flames for analytical applications indicates the maturity of this topic.Studies of atomization mech- anisms particularly those carried out in the presence of matrix species attract more interest and they are considered in section 1.1.2. A method for measuring the collisional widths of absorp- tion lines developed by O’Haver and Chang (see J. Anal. At. Spectrom. 1989 4 165R and section 1.5.2) has now been published (90/3399). The procedure is based on the shapes of calibration curves generated from absorbance data produced by fitting with the help of a computer a model for the transmission profiles obtained when a continuum source is used. A precision of f 0.1 pm was obtained for the elements from Cd to Sr with a spectrometer having a bandpass of between 5 and 12 pm.A few papers have appeared concerned with the analyti- cal utility offlames other than those employing air-C2H2 or N20-C2H2. The determination of Cd in various non-ferrous alloys was improved by the use of an air-C3HS/C4H10 flame (90/1527) and the rapid determination of Cu Mn and Ni in steels with the help of an air-C,H flame was made (91/1264). The measurement of A1 using an O2 enriched air-C2H2 was reported (9 111448). A characteristic concen- tration of 2.5 mg 1-I of A1 was obtained at a C2H2 flow rate of 4.17 1 min-l and an 02:C2H2 ratio of 0.58. Air-CH3(CH2)4CH3 or air-C,H CH3 flames were used for the determination of Fe in copper-nickel alloys after liquid-liquid extractive separation (9 1 /I 367). A character- istic concentration of 0.13 mg 1-’ of Fe was obtained.The use of the N20-C3H8 flame has been described for the determination of Ca and Mg in natural and waste waters (91/910 9111 1 12) and the determination of Mn in steels (9 I/ 1 264). Also of interest in this section is the detection of combustion products by a variety of techniques. Molecular fluorescence stimulated by radiation from an ArF laser was used to monitor NO (90/1851). Laser-induced fluores- cence has also been used to monitor OH in low pressure ( 1- 10 bar) flat flames (90/4 1 79) and both OH and CN have been detected by this technique (9 1/C63 1). This presenta- tion described the use of resonance enhanced multiphoton ionization to detect HCO and CH3 radicals while major species (such as CO C02 and NO) were detected by FT’IR spectrometry.The use of molecular beam sampling with MS detection was also described. 1.1.2. Interference studies Despite the maturity of flame-based spectroscopic proce- dures there is a steady output of publications concerned with the study of interference effects. As in previous reviews (J. Anal. At. Spectrum. 1990,5 19 1 R) much of this literature is concerned with methods for removing or compensating for the various effects thereby ensuring accurate analyses. A comprehensive demonstration of a variety of interfer- ences has been provided by Pszonicki and Skwara (90/2235) as part of a demonstration of the utility of a procedure for overcoming them. The method is a combina- tion of the standard additions and successive dilution methods with the additional feature that if the concentra- tion indicated by the extrapolation procedure is imprecise an excess of a known interferent is deliberately added to swamp the effect of the unknown interference due to some matrix species.The method does not correct for additive interferences such as those due to background or spectral overlap. A number of enhancement effects have been reported. In the determination of Al in an O2 enriched air-C2H2 flame (see section 1.1. l) the characteristic concentration was improved to 1.2 mg l-’ by the addition of a variety of organic reagents containing a phenyl ring with hydroxyl and/or carboxyl groups in the ortho position (9111448). These included aluminon chrome azurol S sulphosalicylic acid and hydrogen phthalate.For the determination of Rh in organic matrices (90/3390) the addition of ethanoic acid produced a detection limit of 0.2 mg 1-’ for atomization in an air-C2H2 flame. In the direct determination of P (90/2230) via measurement of Co following the extraction of the ion pair between molybdophosphate and bis[2-(5- chloro-2-pyridylazo)-5-diethylaminophenolato]cobalt(1~) 2- propanone was found to produce an enhancement owing to an increased aspiration rate. Two other solvents ethanol and methanol were found to increase the aspiration rate but without a corresponding improvement in sensitivity. This was attributed to a decrease in flame temperature. Chinese workers (9 112542) reported remarkable enhancements in the sensitivity for Ru on the addition of oxidizing agents.Factors of 10 17 19 19 and 23 were found for bismu- thate(v) peroxodisulphate(vx) iodate(v) bromate(v) and cerium(xv) respectively. The combination of cerium(xv) and bromate(v) was found to enhance the signal by a factor of 37 with a corresponding detection limit of 20 ng ml-l. Further confirmation of the enhancement effect of amines on the A1 signal in an air-C2H2 flame (J. Anal. At. Spectrom. 1989 4 165R) was provided (911929). TheJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 189R addition of tetrabutylammonium chloride at a concentra- tion of 6% m/m in the final solution gave a detection limit of 4.8 mg 1-1 for the determination of A1 in silicon. The standard additions method was used to compensate for the interference due to iron and calcium.Other Chinese workers reported on the sensitizing action of sodium dodecyl sulphate (9 1/406 9 1/242 1 91/2423). The first report concerned the determination of Cr in plating bath sludges. It was found that dissolution in l0/6 sulphuric acid with the addition of sodium sulphite removed the interference from copper iron magnesium and nickel. The second report (9112421) showed that the sensitivity for Ni could be increased by the addition of sodium dodecyl sulphate (SDS) cetyltrimethylammonium chloride or aniline. The effects of aniline and either surf-actant were found to be additive. The third report (9112423) indicated that the linear range for the determination of V in steels was increased by the addition of SDS. Yan and Zhang have proposed a mechanism to explain this surfactant effect (9012076).In contrast to earlier explanations based on aerosol ionic redistribution (see for example Kornahrens H. Cook K. D. and Armstrong D. W. Anal. Chem. 1982 54 1325) the model was based on reverse micelle forma- tion. It was suggested that the analyte ions in solution attract a group of surfactant molecules whose hydrophilic ends of opposite charge to that on the metal ion species are orientated towards the ion in the centre of the micelle. During the aerosol generation processes each individual analyte entity is eventually completely surrounded by surfactant molecules and on desolvation in the flame they provide a highly efficient micro-environment for the pro- duction of atoms. In addition potentially interfering species of opposite charge should be excluded from the micelle giving rise to an effective protecting mechanism.Supporting evidence for this was presented for the measure- ment of Ca in the presence of a number of anionic interferences including phosphate and aluminium. The addition of 0.02 mol dm-3 SDS completely restored the signal magnitude to that obtained for the same concentra- tion of Ca in a solution containing no potential interferent. Refinements of an earlier method (J. Anal. At. Spectrom. 1989,4 165R) for the correction of physical interferences in a nebulizer by a method based on Fraunhofer diffraction have been made by Kitagawa and Okuyama (9 1/1122). The size of the laser beam dimension was restricted by a 0.2 mm aperture and an improved computer program was used to estimate the background signal more accurately.The procedure was tested on solutions of Cu in sulphuric acid of concentration up to 4 mol dm-3. A comprehensive study of the likely interferences encoun- tered in the determination of Cr in argillites (a type of oil- shale containing 10-20% organic matter 2O-4O0/o clay minerals and 50-55Oh aleurite) was made (90/3591). It was found that accurate results could be obtained with atomiza- tion in an air-C2H2 flame if potassium thiocyanate was added at a concentration of 0.4Oh. The addition of per- chloric acid (0.3%) was found not only to help with interference reduction but also increased the sensitivity. The possible benefits of the addition of dodecylamine hydrochloride were also investigated but the performance was considerably inferior to that of the thiocyanate-per- chloric acid combination.It was suggested that the addition of these reagents had a beneficial effect on the flame chemistry and promoted the formation of volatile chromyl chloride. A characteristic concentration of between 0.07 and 0.2 mg 1-l of Cr was obtained. Chinese workers (90/3450) found that sulphosalicylic acid prevented inter- ferences from aluminium silicon titanium and zirconium in the determination of Mn in alloys. Russian workers reported (91/914) similar benefits from the addition of thiourea to natural- and waste-water samples for the determination of Bi. A detection limit of 0.8 mg 1-l was obtained. For the determination of Mo in the same sample types (91/1293) it was found that the addition of sodium sulphate and ammonium chloride reduced the interferences from calcium iron nickel and zinc.German workers (91/987) found that both hydrochloric acid and strontium were required to remove the depressive effect of 1- hydroxyethylidene- 1,l -biphosphonate on the determina- tion of Ca. The effect was also alleviated by the addition of EDTA. The effectiveness of several procedures for over- coming the depression caused by inorganic phosphate on the determination of Ca were studied by Welch et al. (90/4033). The target analysis was the determination of Ca in urine for which a method based on the addition of lanthanum (20 g 1-l) followed by atomization in an air-C2H2 flame was found to be superior in accuracy to procedures involving (a) the addition of potassium with atomization in an N20-C2H2 flame and (b) the addition of smaller concentrations of lanthanum and atomization in an air-C2H2 flame.The effectiveness of some releasing agents for the removal of the phosphate depression on the determination of Mg has been studied (91/1049). The continuous titration method was used (J. Anal. At. Spec- trom. 1986 1 137R) to study the effects of calcium lanthanum praseodymium and strontium on atomization in an air-H2 flame. Pyrogallol has again been shown (90fC 1753) to be effective in the removal of the depressive effects of phosphate and silicate in the determination of Ba Ca Mg and Sr (J. Anal. At. Spectrom. 1988,3 142R). The continuous titration procedure was also used in this study. The interference of aluminium in the determination of noble metals (Ag Au Ir Pd Pt and Rh) has been investigated (91/1570) and its beneficial effect on the determination of Mn in soil samples in which the presence of iron caused inaccuracies noted (9 111 399).In this study a correlation between releasing action and ionization poten- tial was observed. Posta and Skucs have now published details (911284) of their study of the effect of alkali and alkaline earth metal salts on the atomization of some transition metals in the air-C2H2 flame. As was previously noted (J. Anal. At. Spectrom. 1989 4 165R) the interference arises from the volatilization characteristics of the solid aerosols formed from the pairs of salts. These workers concluded that the presence of magnesium sulphate should be avoided because of its specific interference action. A number of years after drawing attention to the problem (see Thompson K. C.and Wagstaff K. Analyst 1980 105 641) Thompson has presented further results (9UC8181) on the role of trace concentrations of silicate in the determination of Fe and Mn in samples relating to the water supply industry. Again specific instrument dependence was found and for matrices other than potable waters the N20-C2H2 flame was recommended. A steady state kinetic model for the so- called ionization suppression effect has been developed (9 1/C 1797). The model which takes into consideration the radiative recombination collisional excitation and de- excitation of K ions in the presence of excess of sodium accounted for the observed enhancements which were larger than predicted on the basis of ionization suppression due to increased electron number density.Koirtyohann and co-workers have studied (9 1 /C 1 900 90/2200) the unexpected interferences produced by certain oxygen-containing compounds on the atomic absorption signal of a number of REEs and first row transition elements in the N20-C2H2 flame. The effects mainly suppressions were observed for various organic acids amino acids carbohydrates sulphuric and phosphoric acids and are characterized by showing an abrupt slope change at mole ratios of concomitant to analyte of between 1 1 and 2:1. The fact that many of the compounds in question190R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRYy AUGUST 199 1 VOL. 6 contain oxygen and decompose instead of vaporizing when heated was thought to be significant. The effects could be overcome by re-optimization of the fue1:oxidant ratio and were considerably less severe when the sample contained other salts.A partial explanation in terms of solid-phase reactions after desolvation but prior to vaporization was offered. The effects of different mineral acids on the determination of Cd and Pb have been reported (9111497). There appeared to be little difference between hydrochloric nitric perchloric and sulphuric acids and between fuel-rich and fuel-lean flames. Klunder and Boss have again reported (91/C1863) on their studies of ligand interferences in fuel- rich flames. To study the rate of atomization thought to be affected by many interferents the sample was introduced by a single-droplet generator and the atomic population interrogated by AFS with pulsed HCL excitation.Chinese workers (9 1/1155) have examined the quantum chemical parameters of 14 organic complexing agents and studied the possible correlation between an enhancing effect on the atomization of Yb and (a) the charge density on the frontier atom and (b) the bond order between the frontier atom and its neighbouring atom. Huzino has developed a method for the determination of Ca in calcium silicate (91/1294). The sample was ground to a particle size of less than 4 pm and suspended in water. To the suspension was added hydro- fluoric acid and carbon black (J. Anal. At. Spectrom. 1989 4 165R) at a concentration of 0.02% m/v. A linear calibration function was obtained for atomization in an air-C2H2 flame for Ca concentrations up to 500 mg I-'.1.1.3. Sample introduction The methods used for the production and transport of aerosols in analytical instrumentation have been reviewed by Browner (90/3246). The properties that give aerosols their particular usefulness in interfacing bulk liquids sample solutions with various detection systems were discussed and some specific examples of analytical applica- tions given. Reference to flame atomizers was brief and mainly from a historical point of view however the article contains much useful information about aerosol generation and transport and should be read by all practising analytical spectroscopists who rely on aerosols as an integral part of their instrumental techniques. Willis et al.have discussed some practical aspects of handling aerosols for samples containing high concentrations of dissolved solids (9 1 /847). In line with suggestions made by the Instrumental Criteria Sub-committee of the Analytical Methods Committee Analytical Division Royal Society of Chemistry (Anal. Proc. 1984 21 4 9 the decrease in absorbance with time while nebulizing a solution containing an easily atomized metal in a refractory halide matrix was used as a perform- ance parameter. Two different types of spray chamber and burner design were evaluated. Superior performance was obtained from a burner design with a flared slot. In addition to spraying solutions of sodium chloride containing a few mg 1-1 of Cu as the test element a cola drink spiked with A1 and a used gear-box oil diluted (1+4) with aviation kerosene were also used.Drop-size measurements were not made but the relative depression of the Mg signal in the presence of aluminium was used as an indicator of aerosol characteristics. The roles of the position of impact bead and of paddles were also studied and some suggestions made for the basis of comparison of the safety aspects of burners for use with N20-C2H2 flames. This paper provides a useful set of results with which those from future studies in this area may be compared. It is likely that with the rise in interest in flow injection introduction procedures (see later) studies of the tolerance of any new system to blockage and to solute volatilization interferences will undoubtedly be made.Several reports of the use of double capillary nebulization have appeared. Chinese workers (90/352 1) described a system for the determination of some hydride-forming elements and of Hg. The method was described as simple and rapid and was applied to the determination of As Bi Hg and Sb in geological samples. The lower limit of the working range was found to correspond to 10 mg kg-' for As and to 1 mg kg-l for the other elements. A study of the flame profiles of Ca Cr Cu and Fe in the presence of several organic solvents (introduced in one branch) and a non-ionic surfactant (introduced with the analyte in the other branch) has been made by Bagdi et al. (91/942). The solvents included IBMK acetone benzene toluene xylene isobutyl acetate and tetrachloromethane. The presence of the organic solvents (apart from tetrachloromethane) had a negligible effect on the influence of the surfactant poly- oxyethylene glycol nonylphenyl ether.Tetrachloromethane was found not unexpectedly to decrease markedly the sensitivity for Ca and Fe. The results were compared with the nebulization of emulsions of organometallic com- pounds stabilized with the surfactant (see J. Anal. At. Spectrom. 1987 2 182R and J. Anal. At. Spectrom. 1990 5 193R) and the differences observed were attributed to the interaction of the surfactant with the inorganic analyte species. The use of a similar device was proposed by Watling et al. (9111463) for the addition of an ionization suppressant to flames into which organic solvent samples were being introduced. It was found that the procedure resulted in considerable savings in costs and time over the addition of organic-based suppressants and these workers suggested that the procedure should be useful for the determination of wear metals and additives in oils.Stupar has also described such a procedure for use in conjunction with an ultrasonic nebulizer device (91/1103) in which the two solutions are mixed on the face of the piezoelectric transducer. Possible applications to flow injection (FI) methods and for internal standardization in ICP-OES were suggested. Further studies by Berndt on the hydraulic high pressure nebulizer have been described (90/1929 91lC498). The latter report indicates that organic solvents can be success- fully introduced into flame atomizers and thus the device can be used as an interface between HPLC and atomic spectrometry detectors (see under 1.1.4).The use of the system in the FI mode with sample volumes of just 1 or 2 ply was mentioned. Gustavsson has reviewed the design and application of various devices for interfacing HPLC and FI procedures with atomic spectrometry (91/1056 91/1098). Details of these devices have appeared in previous Updates (J. Anal. At. Spectrom. 1990 5 195R and J. Anal. At. Spectrom. 1989 4 167R). Robinson and Choi described a system for the production of Hg atoms (9013353) which used a thermospray nebulizer to introduce the sample solution into a circular air-C2H2 flame. The flame gases were entrained in the vertically mounted side arm of a quartz T-cell. The sensitivity was 0.2 mg 1-l and the detection limit was 10 ng ml-1. Credit must go to workers at Dalhousie University for publishing in this field of considerable maturity what appears to be a completely new way of generating an aerosol for introduction into a flame atomizer namely by the use of an atmospheric pressure helium plasma (90/3495).A 90 kHz discharge was produced between an upper electrode (copper or chromel) mounted 10- 1 5 mm above the surface of the sample solution contained in an 1 1 mm diameter vial into which a counter electrode was inserted. Some details of the capability of the power supply were provided in an earlier publication concerned with sputtering (Stephens R. J. Anal. At. Spectrom. 1988,3 1 137). The signal was found to increase with both sodium chloride concentration andJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL.6 191R power. However the rate of transport to the flame was only 0.09 ml min-l and thus the sensitivity and detection limits were correspondingly poorer than those obtained with conventional nebulization. In a study of droplet size no diffraction pattern was observed with the laser Fraunhofer method but solute volatilization interferences were ob- served when Ca was determined in the presence of phosphate or aluminium. The mechanism of aerosol forma- tion was therefore considered to be mechanical disruption of the surface followed by rapid evaporation of the solvent. 1.1.3.1. Discrete procedures. The supposed advantage in terms of improved detection limit which accrues by the use of a procedure in which a relatively large volume of sample (adequate for conventional continuous nebulization) is taken through a preconcentration procedure which pro- duces a limited volume (so that discrete nebulization is employed) was evaluated critically by Beinrohr (90/3958).The theoretical argument was supported by results for the determination of Fe and it was concluded that the improve- ment in detection power of the preconcentration procedure may be more than offset by the reduced sensitivity and poor precision of the discrete nebulization step. Workers con- templating the development of such a procedure are advised to read this paper closely. In the meantime a procedure for the determination of Mo in geological and biological materials in which pulse nebulization into a flame atomizer was used has been developed by Monte and Curtius (9013479).A preconcentration procedure involv- ing the sorption of the Mo complex with the 0,O-diethyl ester of dithiophosphoric acid onto activated carbon with release into nitric acid gave rise to only 1 or 2 ml of solution from which 100 pl sub-samples were dispensed by a micropipette. Rocks described such an analysis (90/C4041) the determination of Cu and Zn in 100 pl samples from a hospital baby care unit. It was pointed out that the discrete nebulization procedure avoided the risk of contamination from reagents. Chinese workers (9 1/374) described the use of this same volume of sample solution in the determination of Cu Mg Mn and Zn in aluminium alloys. The final solution contained strontium as a releasing agent and was 1-2% m/v in dissolved solids; an air-C2H2 flame was used.In contrast Gruber and Herbauts (9 1 / 1 490) used an N20-C2H2 flame for the determination of A1 in solutions containing high concentrations of dissolved solids. However by the addition of tetrabutylammonium chloride Chinese workers (91/1469) were able to use an air-C2H2 flame in the determination of A1 in silicon. What appears to be the standard volume for discrete nebuliza- tion 100 p1 was taken. With Zeeman-effect background correction a detection limit of 8 mg 1-l was obtained and it was implied that this was an improvement on the value of 1 1.5 mg 1-l obtained with conventional nebulization. The Chinese workers mentioned in the previous section de- scribed the adaptation of the branched capillary (90/352 1) to a discrete nebulization mode (90K2046).As well as suggesting the possible use for chemical vapour generation procedures the device was used for the addition of releasing agents and ionization suppressors. Russian workers (91/C488) described the use of two discrete procedures. Either sample volumes of 1 pl were introduced via the nebulizer or samples were introduced on a probe inserted directly into the jlame (or plasma). It appears as though evaporation from the probe was assisted by either ultrasound or external heating (see also J. Anal. At. Spectrom. 1990 5 193R and J. Anal. At. Spectrom. 1989 4 167R). Also of interest is a report of the combination of discrete nebulization with molecular emission spectrometry for the determination of B in steels (90/2221).Further applications of the injection device constructed by Futekov et al. have been developed (90/4010). In addition to the introduction of a discrete sample volume the procedure uses ensemble summation of successive signals to improve the SIN ratio (J. Anal. At. Spectrom. 1987 2 183R). The determination of Bi Cu and Zn at concentrations of 5 0.5 and 0.25 mg kg-l respectively in sodium chloride and of Cu Fe and Pb at concentrations of 0.47 3.7 and 0.1 mg kg-' respectively in ammonium fluoride was achieved. Further details of the device are given later in the flow injection section. A procedure for the determination of Au with direct sample introduction into the flame by means of a silica boat was described (91/418).After extraction with IBMK from an acid mixture a 50 pl sample was placed in the boat which was transported by means of a rotating turntable. However a precision of only 15% RSD was claimed. Discrete amounts of Co were introduced by evaporation of some volatile derivatives (91/7) by a procedure appar- ently developed independently by two Spanish research groups but published in one paper. A number of com- pounds were studied but the final procedure adopted for the determination of Co in steel bronze and brass was based on derivatization with trifluoroacetylacetone. A 5 pl sample of the final solution was injected into a heated vessel mounted externally to the spray chamber. A similar procedure has been used for the introduction of the trifluoroacetylacetone derivatives of Cr and Fe as well as of Co (91/2576).Further details of the procedure are given in section 1.3 (Chemical Vapour Generation). 1.1.3.2. Atom-trapping techniques. Chinese workers (90/1263) have reviewed the use of both water-cooled atom traps (WCATs) and slotted tube atom retarders (STARS). In contrast to previous review periods there would apear to be no other publications or conference presentations con- cerned with the WCAT. Several researchers have described the use of a STAR. Bums et al. (9013418) used an FI method for the determination of Pb in copper-based alloys. Although the detection limit (0.13 mg 1-l) was degraded in comparison with that for continuous nebulization (0.09 mg l-l) a throughput of 50 samples h-l was possible and the life of the quartz tube was extended.Zhang and Yuan (9 1/C2 150) described a procedure for the determination of Pb in water in which sulphydryl cotton fibres were used for preconcentration and matrix isolation. Sensitivities 2-3 orders of magnitude higher than those obtained with conventional flame techniques were claimed. The perform- ance of a commercially available device has been described on a number of occasions (90/C1750,90/C3037,91/2401). Improvements in detection limits by up to a factor of 4 were obtained for a number of elements normally deter- mined in fuel-lean to stoichiometric air-C2H2 flames. 1.1.3.4. Sample introduction by flow injection. The inter- est in FI procedures noted in last year's Update (J. Anal. At. Spectrom. 1990,5 194R) has been sustained.Several of the prominent workers in this area contributed to a review book (Flow Injection Atomic Spectroscopy ed. Burguera J. L. Marcel Dekker New York 1989) from which some chapters have been individually abstracted (9 1/155 9 1/ 1 3 1 1 9 1/ 1 3 12). The book while presenting useful material to illustrate the scope of flow injection atomic spectrometry (FIAS) contains few references after 1986 and thus is somewhat out of date in terms of recent developments in what has proved to be a rapidly growing area of research activity; not just for flame-based techniques but also for most other types of analytical atomic spectro- metry. Tyson has reviewed the relevant 1988 and 1989 literature (9 1 / 1498). Attention was drawn to the variety of FI procedures described for preconcentration and separation of analyte and matrix species.This aspect of FIAS has been further elaborated in a series of conference presentations describing ongoing work in Tyson's research group (90K1606 90/C3038 91/C1854 91K2100) and was also highlighted by RhiiCka (911C1853). Features of a new192R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991 VOL. 6 commercially available HAS system introduced by Perkin- Elmer have been described by company personnel on several occasions (90/1537 90/C2050 90/C2908 90/C2982 9 1/C788 9 1/C1746 9 1/C1883 9 1/C2098). Carbonell et al. have investigated some findamental parameters of the basic FI manifold interfaced to an FAA spectrometer (9 1/3 10). These parameters included flow rate nature of the carrier stream (use of surfactants or of organic solvents) and the use of compensating fluid flow introduced at a connector just prior to the nebulizer.No major new effects were observed and it was found that the use of a water carrier stream with no compensation gave satisfactory results for the determination of Cu Mn and Pb in sewage. Kuban et al. (9 1 /2523) also used a simple single- line manifold for the determination of Mg in aluminate luminophors and Zhou et al. (91/1273) determined Ca K Mg and Na in surface waters. A manifold containing a UV-visible absorption spectrophotometer in series with an FAA spectrometer has been used for the determination of pairs of components in silicate rocks (90K2038). A scheme for the eventual determination of ten constituents was described.A third group of Chinese workers ( 19/ 1 52 1) used this manifold design for the determination of Li in brine and of Pd in geological samples following extraction of the mercaptobenzothiazole complex into 4-methylpentan-2- one. The single-line manifold has also been used for the introduction of slurries. For the determination of Cu Mn and Pb in sewage sludges (91/310) the samples were partially digested in sealed Pyrex glass containers in a microwave oven. After dilution to volume with water a 500 pl sub-sample was injected. Accurate results were obtained for the analysis of two reference materials and detection limits of 60 50 and 300 ng ml-l for Cu Mn and Pb respectively were claimed. For the determination of Fe and Zn in foods (9 1/ 1 584) slurries were prepared by grinding the dry sample to pass through a 1-2 mm sieve followed by suspension in water.A specially designed Babington V- groove nebulizer was used with an additional oxidant inlet. Again 500 p1 sub-samples were injected. Calibration was effected by injection of slurries of various concentrations of a white bean homogenate whose composition with respect to the analytes had been established by analysis following dry ashing and dissolution in dilute (1 + 1) hydrochloric acid solution. Detection limits of 0.6 and 0.3 mg 1-l for Fe and Zn respectively were obtained. Bums et al. (9013418) determined Pb in copper by injection of the sample into a single-line manifold with a flow rate slightly above that required by the suction developed by the nebulizer.The excess of fluid was diverted to waste at a T-connector just prior to the nebulizer. With the aid of a slotted tube atom retarder a detection limit of 0.13 mg 1-l for a 250 pl injection volume was obtained. Workers at Xiamen University (9 1 /C2 142) demonstrated the possibility of determining Cu in aluminium with an FI system incorporating on-line electrolytic dissolution. Gradient chambers have been used for the generation of concentration gradients and dilution of samples. Chinese workers (9112483) used the rise curve produced on switch- ing from blank to concentrated standard (see Tyson J. F. and Appleton J. M. H. Talanta 1984 31 9) to calibrate for the determination of Mg in waters and geological materials. Good accuracy and precision were claimed. De la Guardia et al.(90/4011) used a merging zones manifold (to add lanthanum) for the determination of Ca K Mg and Na in water. The well-stirred gradient chamber was located between the merging point and the spectrometer. The use of two such chambers of volumes 827 and 2245 pl was evaluated. Calibrations up to several hundred times less sensitive than normal could be obtained thereby extending the working range by more than two orders of magnitude. These workers were unable to use the exponential concen- tration-time relationship which is obtained for a step change in concentration for single-standard calibration but obtained satisfactory results from empirical relationships of the form logc=A + tlogB where c and t are concentration and time respectively and A and B are experimentally determined coefficients.Workers from the same research group (91/25 14) used the same manifold for the determina- tion of Pb in gasoline. In this procedure the mixing chamber served to produce an emulsion of the injected sample. On- line de-metallation of the alkyl compounds by reaction with iodine in petroleum spirit was used to permit the determi- nation of total lead. As the sensitivities for tetraethyllead and tetramethyllead were considerably different in the absence of the iodine reagent it was suggested that this could be exploited as the basis for a method of speciation. After establishing the calibration function for each of the species two measurements on each sample were made (with and without the iodine). Results for the analysis of synthetic mixtures appeared to be encouraging.Initial results on the use of wide-bore tubing (1.5-5.0 mm id.) for on-line dilution have been presented (90/C 1606 9 1 /C790). Prob- lems due to differences in physical properties between the injected solutions and the carrier stream were encountered. For the determination of some clinically relevant elements Araujo and Lima (9011549) used three different FI mani- folds to cover the range of concentrations encountered. On- line dilutions by stream splitting and merging of diluent were made. A procedure incorporating on-line dialysis has been developed for the determination of total and free Ca in milk (van Staden J. F. and van Rensburg A. Analyst 1990 115 605) which has been extended to include the determination of Cl(9 1 / 1 5 1 4).Total Ca was determined by solution spectrophotometry and free Ca by FAAS. The dialysis unit separated the free Ca and for an injection volume of 30 pl provided an on-line dilution allowing determinations over the range 100-1 500 mg 1-l. Interfer- ence from phosphate was overcome by the use of an N20-C2H2 flame and an ionization suppressant (2.5 mg ml-l potassium solution) was merged just after the dial y ser. The possibility of exploiting on-line chemical reaction for the development of indirect procedures was discussed by Hansen (90lC2867) under the title of ‘FIA Conversion Techniques’. The benefits of the controlled kinetic features of FI were stressed. Esmadi and Attiyat (9 1/1528) described a procedure for the determination of either ammonia cyanide or thiosulphate. A distilled water carrier stream was aspirated by nebulizer suction at 3 ml min-l through a manifold which contained a column (2.8 mm x 7 cm) of solid silver chloride and glass beads (1.9 mm).The dissolved silver was detected at a downstream FAA spectro- meter. Detection limits of approximately 10-6 mol dm-3 were obtained for an injection volume of 200 pl. Li and Zhang (911424) determined Si in steels by an indirect procedure based on the formation of Molybdenum Blue off- line. A detection limit for Si of 0.25 mg 1-’ was reported. Procedures for the determination of two drugs (methadone and chlordiazepoxide) have been developed in the continu- ing programme of research in this area by Valcarcel’s group at Cordoba (91112 91/2469).The manifold contains a reductor column of zinc or cadmium metal which releases an equivalent amount of metal ions into the carrier stream on reaction with a reducible species. For the determination of chlordiazepoxide (9 1/ 12) the sample solution had a pH of 3 and so a measurable zinc blank signal was obtained. This was subtracted from the signal obtained on injection of the sample solution (200 pl). The working range was 2.0-25 mg 1-l with a sampling frequency of 150 h-l. As the reaction is specific to the N-oxide group of the target molecule the method is selective for chlordiazepoxide inJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 193R the presence of other 1,4-benzodiazepines. For the determi- nation of methadone (91/2469) a cadmium column was used and a 90 pl sample volume was injected giving a working range of 5-50 ng ml-I.The procedure was used to assay the drug in pharmaceu- tical preparations and in urine. For the latter sample the drug was extracted from alkaline solution into dichloro- methane which was evaporated and the residue taken up in distilled water. The majority of HAS publications in this review period concern the performance of on-line preconcentration and matrix separation procedures. Although a small number of papers have appeared in which liquid-liquid extraction (LLE) or precipitation have been used by far the greatest activity is in the development of solid-phase extraction (SPE) procedures. Kuban and co-workers have described (9 11323) an LLE manifold coupled indirectly to a flame spectrometer and its application to the determination of Cu in water from power station cooling circuits (9 1 / 1 25 5).The analyte was extracted at pH 5.05 as the APDC complex into IBMK and after phase separation 100 or 1 50 pl sub-samples were injected into an air carrier stream for direct introduction to the spectrometer. The phase separator was a flat membrane type and it was found that microporous Teflon had a superior performance to that of hydrophobized cellulose. The use of the FI valve in this position in the manifold provides an interface between the extraction manifold and the transport manifold. In general for FI-LLE-FAAS there is a mismatch between the optimum flaw rates for these two functions. Efficient extractions are only obtained at low flow rates and in order to obtain a real preconcentration it is necessary that the flow rate of the organic phase be less than that of the aqueous sample phase.Depending on the volume injected the working range was 20-900 or 2-500 ng ml-l with a sample throughput of 40 h-l. These workers concluded that although the procedure had performed satisfactorily it had no advantages in comparison with the use of solid-phase extractants. Tyson and co-workers have reported on some further attempts (90/1470 91K1864) to exploit on-line precipitation for sample clean-up and pre- concentration. The possibilities for the removal of interfer- ence effects were demonstrated (90/1470) for the determi- nation of Ca in some synthetic rock solutions containing aluminium phosphorus and silicon.The Cordoba group has published another method for determining trace metals in mineral samples (J. Anal. At. Spectrom. 1990 5 195R) with a procedure for the measurement of Co by precipita- tion with 1-nitroso-2-naphthol (90/1176). A merging stream manifold was used in which the sample stream (suitably buffered and dosed with citrate masking agent) flowing at 7 ml min-l merged with the reagent stream flowing at 1 ml min-l. After passing through a 70 cm reaction coil the precipitate was collected on a stainless-steel filter. Dissolu- tion was effected by forward flushing with ethanol. A stream-switching valve located between the filter and the spectrometer diverted the matrix components to waste rather than passing them through the nebulizer. By taking a 100 ml sample volume it was possible to achieve a detection limit of 1 ng ml-1 at a sampling frequency of 1 h-l.However by reducing the sample volume to 10 ml a more reasonable throughput of 40 h-l was possible with a detection limit of 6 ng ml-I. Accurate analyses were obtained for the determination of Co at concentrations of between 2 and 20 mg kg-l in silicate rocks. An indirect precipitation procedure for the determination of chlorhexidine has been developed (9 1/2 189) by another Spanish group. The precipitate produced on injection of sample solution into an ammoniacal copper carrier stream was retained on a paper or plastic filter and subsequently dissolved in nitric acid. A working range of 5-20 mg 1-1 was obtained for Cu. Aspects of the design and application of in-line columns for solid-phase extraction (SPE) procedures have been considered by Fang (90/C2047).By combining SPE with chemical vapour generation it was possible to achieve detection limits of 1 2 and 2 ng 1-1 for Bi Hg and Se respectively. Use of columns of suitably small dimensions allowed on-line enrichment factors of 25-30 to be achieved for sample volumes and throughputs similar to those obtained for conventional introduction. Coetzee et al. (9014016) devised a method for the determination of Ag in bore-hole water at concentrations down to 4 ng d - l . The column (1 mm x 3 cm) contained basic alumina and was inserted in a single-line manifold between the valve and the nebulizer. The carrier stream was propelled by a dual piston HPLC pump which could deliver either sample solution a water carrier or an ammonia regenerant solution.After loading the column at 5 ml min-l the accumulated Ag was removed by injection of the eluent solution (500 pl of 2 mol dm-3 nitric acid) into the water carrier at an optimized flow rate of 5 ml min-l. It was found that the pH of the sample solution was critical with a maximum retention at pH 4.0 whereas the sampling flow rate was not. In order to avoid low recoveries of Ag due to the formation of ammine complexes the column was washed thoroughly with water after regeneration. The total analytical cycle time appeared to be about 10 min. High concentrations of various calcium magnesium and sodium salts (0.1-0.5 mol dm-3) did not interfere. Bennet and Dean (91/C801) presented preliminary results for the separation of Co as the chloro complex from iron and nickel which are potential spectral interferents.An injection valve was used to control the volume of sample solution loaded onto the column rather than rely on a procedure based on constant delivery from a pump for a known time. An evaluation of a number of possible solid-phase reagent materials for the preconcentration of A1 in dialysis concentrates has been made by Periero Garcia et al. (90/3478). It was concluded that Chelex 100 and Amberlite IRA-400 were the most suitable materials although it was pointed out that the latter material cannot be used when the ethanoate concentration exceeds 40 g l-l and requires a chloride concentration of at least 3 g 1-1 in both standards and samples. The sample solution (up to 25 ml) was introduced by injection through a septum into a buffer carrier stream.A switching valve located between the column and the spectrometer diverted matrix components to waste during sample loading. The eluent was 100 pl of sodium hydroxide solution. The performance of the method was evaluated for the determination of A1 in a dialysis concentrate which contained less Al than could be detected by direct analysis by ETAAS. Accurate recoveries were obtained for concentrations of spikes of between 50 and 190 ng ml-l. The performance of another chelating resin containing iminodiacetate functional groups Muro- mac A-1 has been evaluated by Hirata and co-workers (90/1968). A fully automated manifold incorporating five 3- way and two 2-way solenoid valves was constructed in which the column (4 x 7 mm) was mounted directly on the outside of the spray chamber.The operation of the manifold appeared to consist of loading the sample through the column by timed switching of the appropriate valves followed by blowing out the sample solution remaining in the manifold between the switching valve (where the eluent was introduced) and the column by switching in a stream of argon. Unless this was done a reduced peak height sensitivity was obtained depending on the length of tubing between the eluent switching valve and the column (lengths of up to 100 cm were investigated). This effect was discussed in terms of dispersion during the loading but no comments were made on the possible role of dispersion of the leading edge of the eluent stream during elution which194R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL.6 seems a more likely explanation. The column was used to preconcentrate Cd Cr Cu Fe Mn and Zn with enrichment factors of between 90 and 180 obtained for 20 ml sample volumes. The sampling rate was 13 h-l and the detection limits were between 0.14 and 2.1 ng ml-l. Accurate analyses of some biological reference materials for Cd and Cu were made. Kuban et al. have reviewed the use of chelating material for FI preconcentration (91/2239) and made a detailed comparison of some materials containing bound oxine or diethylenetriaminetetraethanoic acid (DTTA) functional groups (91/898) for the retention of Cu. A six-way five- column injection device was used which contained five columns (3 mm x 2.6 cm) in parallel.Samples were buffered to pH 4.2 and loaded for up to 5 min at a flow rate of up to 11 ml min-l although 5 ml min-l were typically used. The accumulated Cu was eluted in the reverse direction by a stream of 2 mol dm-3 hydrochloric acid. Enrichment factors of up to 100 were obtained with sampling frequen- cies of up to 70 h-l. Kuban et al. demonstrated another useful feature of FI-SPE-FAAS namely the greatly in- creased linear range. By control of the volume of sample loaded linear calibrations were obtained from the detection limit (0.3 ng ml-l) to 200 pg ml-l (60 s load time). Good agreement between the FI procedure and an ETAAS procedure was obtained for the analysis of power station cooling circuit water.A simple version of this procedure has been described by another Czechoslovakian group (91/245) in which a column of the oxine material was incorporated into the nebulizer capillary. A known volume of buffered sample solution was loaded onto the column by the action of nebulizer suction. After aspirating a water wash the copper was eluted with 2 mol dm-3 hydrochloric acid solution. Peak area was used. as the quantitative parameter. The dynamic range was from the detection limit of 0.3 ng ml-l to 5 pg ml-l (breakthrough) with precisions better than 5% RSD for concentrations above 25 ng ml-l. A similar procedure was described by Karakaya and Taylor (9011 923) for the determination of Cd in urine. A column of alumina was used and the flow rate was externally con- trolled by means of a peristaltic pump.A detection limit of 1 ng ml-l was obtained. One problem for on-line micro-column procedures is the dimensional instability of some resin- based solid phase extractants. The cycle of swelling and shrinking which occurs when the pH of the solution is changed can lead to blockage of flow lines or frits on the one hand and the appearance of voids and channels on the other. Several publications have reported on the use of silica-based materials. Fang and Welz (90/ 1 175) described a procedure which used 8-hydroxyquinoline immobilized on controlled pore glass (CPG) in ultra microcolumns fabricated from Eppendorf pipette tips. The column volume was only 120 pl and only 1.6 ml of sample solution were required which gave a throughput of 120 h-l.Knotted tube conduits were used to minimize the dispersion arising from flow in the tubing connecting the column and the spectrometer and it was found that a conical reactor shape gave a lower dispersion than a cylindrical packed-bed reactor. Enrich- ment factors of between 25 and 31 were obtained for Cu Cd and Pb and the potential of the procedure for the determination of these elements in sea-water was demon- strated by recovery from synthetic samples. The repetitive determination of Cu at a concentration 100 ng ml-l had an RSD of 1 Soh (n= 8 1). Some preliminary results for the use of this material for the determination of A1 have been presented (9 1/C785). The precipitation of A1 from solutions of high pH required to get efficient retention was pre- vented by the addition of malonate as an auxiliary complexing agent.Enrichment factors of up to 70 were obtained. Other workers have immobilized 8-hydroxy- quinoline-5-sulphonic acid on CPG (9 1 / 1 077) and used this material in a simple single-line unidirectional flow manifold for the determination of Cu Cd Hg Mg Pd and Zn. For a 5 ml sample volume detection limits of 0.5,0.6,25 1.0,lO and 1 .O ng ml-l respectively were obtained for a sampling rate of 20 h-l. Metals were eluted from the column by the injection of 100 pl of 2 mol dm-3 hydrochloric acid solution at a flow rate of 2 ml min-’. The column was also loaded at this flow rate. The capacity of the extractant was found to be 5 x 10-3-8 x mol g-l. The use of a commercial prototype preconcentration unit was described for the determination of Pb in tap water (90/3512).A 3 x 50 mm column containing 8-hydroxyquinoline immobilized on silica was mounted in the injection loop of a six-port rotary valve. The sample solution was merged with a buffer solution containing a cocktail of masking agents (0.2 mol dm-3 boric acid 2% triethanolamine 2% thiourea and 2% acetylacetone) to prevent the interference of aluminium copper iron and zinc. After loading the column was inserted into a water carrier stream by rotation of the valve and the residual buffer components were eluted. The retained Pb was eluted by the injection from a second valve of 1 mol dm-3 hydrochloric acid. A number of tap water samples containing between 5 and 80 ng ml-l of Pb were analysed giving results which were statistically indis- tinguishable from results obtained by a collaborating laboratory using ETAAS.Lancaster and RdiiEka described an SPE procedure in which a C,*-based support material was used (911C1859). The first step in the procedure was to load the ligand onto the column this was followed by the analyte solution and finally by a solvent of reduced polarity to elute the metal ligand complexes formed in the column. The use of a commercially available automated system which incorporates a column of cellulose with iminodiacetic acid functional groups has been described (90/C2984). Also of interest in this section are some closely related procedures. Bulgarian workers are developing two lines of research that bear more than a superficial resemblance to FI.Havezov and Detcha described preliminary work with a controlled dispersion device (91lC1763). In this technique an injection valve is not used but discrete volumes of liquid are intercalated by controlled stream switching and pump speed. The ‘dosage system’ developed by Futekov has been further modified (90140 10). This merging stream manifold system is a cross between a pulse nebulization system and a controlled dispersion system. The driving force for liquid transport was provided by nebulizer suction which drew fluid either from a reservoir of wash solution or from a sample vial in the autosampler tray or both. The wash reservoir was isolated by an electronically controlled valve and the autosampler probe was also electronically con- trolled. The sequence of operations was that with the valve open and the probe up a wash solution was delivered to the nebulizer.The probe was then inserted into a sample and the valve was closed. The air in the branch of the manifold from the merging point to the autosampler provided a bubble which prevented dispersion of the leading edge of the sample slug. The probe was withdrawn after a con- trolled time and shortly after the rear of the sample slug passed the merging point the valve was opened again allowing wash solution to flow. The net result was that a discrete sample volume sandwiched between two air bubbles sandwiched between the wash solution was intro- duced into the nebulizer. There was therefore no on-line dilution. The system was used to determine Bi and Zn in sodium chloride and Cu Fe and Pb in ammonium fluoride.Sample solutions containing up to 30% m/m dissolved solids were successfully handled. Schulze et al. (9 1 /C 1698) compared results obtained for the determination of Cu in various water samples with three different methods includ- ing FI-SPE-FAAS. By using a system of three columns inJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991 VOL. 6 195R parallel a throughput of 160 h-I with an enrichment factor of 15 was obtained. A number of FI-AAS papers are concerned with the on- line derivatization of the analyte to a volatile derivative. These results are considered in more detail in section 1.1.3. For example methods for the determination of Bi in turbine blades (a matrix with a high concentration of nickel) (91/C1782) Bi in various non-ferrous metals (90/35 11) and Se in blood (9012 194) have been described.A procedure which might be considered gas-phase FI(90/1989) has been evaluated for the determination of Hg and some organom- ercury compounds by Baeyens and Leermakers. The vapour phase analyte species were trapped on gold coated glass beads and after preconcentration thermally desorbed. Under these conditions the organomercury compounds decomposed with the release of Hg for detection by conventional cold vapour absorption. It was found that not all of the Hg was released and a second desorption at a somewhat higher temperature was required. As there was a correlation between the Hg compound and the extent of release during the two steps of the desorption some information about speciation was obtained.1.1.3.5. Solid sample introduction. Few papers concerned with the introduction of solids directly into flames have appeared in this review period. As has been noted already (see above) the Ca content of a calcium silicate material was determined by the nebulization of a suspension of the ground material in water (9 1 ~ 2 9 4 ) and FI procedures have been used to analyse partially digested sewage sludge slurries (9 1/3 10) and some food slurries (91/1584). Morales et al. (9 1/247 1) described a procedure for the determination of Co Fe Mo and Ni in petroleum industry catalysts by slurry nebulization of the partially digested samples after heating with a mixture of nitric and phosphoric acids in closed vessels in a microwave oven into an air-C,H flame.1.1.4. Chromatographic detection The hydraulic high pressure nebulizer has been adapted as a method of coupling HPLC and FAAS (9 1 / 1254). Compared with conventional nebulization an increase in peak area of an order of magnitude was obtained for Cu. The impor- tance of the position of the impact bead was stressed. The use of the system was illustrated by the separation of FeI1 and Fell1 on a 10 pm 150 mm Spherisorb column. The mobile phase was methanol-0.05 mol dm- ammonium ethanoate (30 + 70) adjusted to pH 4.0 with ethanoic acid and the flow rate was 1.0 ml min-'. Iron speciation by HPLC with both electrochemical and FAAS detection has been described (9 1 /C 1 80 1 ). Robinson and Choi (9 11292) described a thermospray interface for HPLC-FAAS.The system was used for the determination of chlorophylls (via Mg absorbance) and in particular the monitoring of duckweed chlorophyll whose destruction appeared to correlate with the presence of heavy metals. The possibility of using this phenomenon as an indicator of heavy metal presence was suggested. An improved performance over this type of coupling was obtained for the determination of ionic alkyllead corn- pounds from a system in which post-column ethylation was used (90/1990). Sample components were separated on 5 pm Nucleosil CI8 with aqueous 80% methanol containing 0.06% of ammonium tetramethylenedithiocarbamate at 1 ml min-' and ethylated by reaction with sodium tetraethyl- borate. The ethylated species were detected in a quartz tube furnace after gas-liquid separation. Detection limits for alkyllead compounds were about 0.1 ng with good discrimi- nation over inorganic lead (the sensitivity for PbI1 was several orders of magnitude less).A half-replicate 25 factorial design was used for optimization of the post- column reactor-separator-atomizer system. A post column derivatization system for the determination of arseno- betaine arsenocholine and tetramethylarsonium cations has been devised (9 1 / 1 5 7). The analytes were separated by HPLC and the methanolic eluent nebulized by the thermos- pray effect and pyrolysed in a methanol-O2 diffusion flame to give the hydride on reaction with excess of H2. The arsine was then atomized in a cool 02-H2 diffusion flame. As AsV was also derivatized and no signal was obtained without the post-thermospray H2 it was concluded that the generation of arsine was thermochemically mediated.A reversed-phase HPLC system directly coupled to a spectrometer has been used to characterize the metal composition of metallothionein isoforms (90129 14). The analytes were Cu Cd and Zn and the matrices included a crude extract of turkey hen liver. The speciation of organic Hg compounds in fish by capillary GC with AAS detection was described (9011 209). The column eluate was pyrolysed at 700 "C to give a limit of detection for methylmercury of 0.1 ng which corresponds to 0.04 mg kg'l in the sample. Some preliminary information about a GC procedure for the determination of organolead and organotin compounds with a quartz tube atomizer has been provided (90/C2 103).Kitagawa and co-workers de- scribed a 'separative column atomizer' (901333 1) consisting of an alumina tube packed with graphite granules coated with gold or platinum or mixed with tin powder. The ability of the column to separate the vapours of Cd Hg and Pb was studied for the temperature range 800- 1400 "C. The device was used for the determination of Hg (90/3337) in various rat tissues. Also of interest in this section is a brief review of atomic spectrometry detection for chromatography (9 1/2 176). 1.2. Electrothermal Atomizers Electrothermal atomization is a mature technique and one would expect the number of papers in the literature to be reaching a plateau if not decreasing. The opposite seems to be the case.During the period of this review the main area of interest is that of sample introduction in particular methods of preconcentration. Clearly analytical scientists are being asked to determine ever decreasing concentra- tions in smaller and smaller samples. While electrothermal atomization has the clear advantage of being able to handle small samples directly we now appear to have reached the point where the detection limits of ETAAS are no longer adequate. While many of the reports in this year's review show considerable imagination and innovation there is still a large group following in the footsteps of early workers and arriving at the same destination though somewhat later! The opening comments from last year's review (J. Anal. At. Spectrom.1990 5 179R) still apply. Littlejohn (9 1/C735) indulged in some crystal ball gazing in reviewing the state and status of ETA in AS. The increase in our knowledge of ETA chemistry combined with the instrumental sophistication at our disposal has made it possible to perform analyses previously considered to be difficult with a minimum of sample preparation and without the need for complex calibration procedures. Apart from the use of ETA in AS the graphite atomizer has become an important vaporization and atomization system for other techniques such as AES furnace non-thermal excitation spectroscopy (FANES) ICP ICP-MS and laser- excited AFS. 1.2.1. Atomizer design and surface modijication Interferences in the double-tube design discussed last year (J. Anal. At. Spectrom.1990,5 179R) were studied by Xuan (9 1/1467). The interference of calcium chloride cobalt HC1 HNO HC104 iron nickel magnesium chloride and196R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRYy AUGUST 199 1 VOL. 6 sodium chloride on the determination of Pb and Cd was studied but no conclusions were presented in the abstract. Chan (91/384) applied this design to the determination of Pb in steel and waste-waters. Compared with the conven- tional graphite tube interferences from calcium chloride HN03 iron and sodium chloride were reduced and sensi- tivity increased by 1.42-fold. Only one paper discussing probe atomization from Chinese workers (9 1/1441) was received during the prepa- ration of this review. These workers prepared the probe by carbonization of a graphite rod followed by coating with zirconium and used it to determine Au in geological samples. The detection limit and sensitivity were improved and interferences reduced using the probe.Some work continues on different graphite tube designs. The use of metal- or metal carbide-coated graphite surfaces has been investigated by Russian Chinese and Japanese workers. This review year coatings of tantalum seem to be the most popular. Wu et al. (91/1438) deter- mined Sc in geological soil and sediment samples with a tantalum foil-lined graphite tube with lanthanum and ammonium hydrogen carbonate as chemical modifiers. The sensitivity was enhanced approximately 1 %fold tube life- times were greater than 600 cycles and the method showed no memory effect with a lower atomization temperature good accuracy and effective elimination of many interfer- ences.Long (91/450) appeared to use a tantalum-coated device similar to a L'vov platform inserted into a graphite tube to determine As in food-grade phosphoric acid. A prior extraction was performed into 4-methylpentan-2-one be- fore back-extraction into 0.4 mol dm-3 HN03. The internal gas was 8-10% Hz in Ar which prolonged the useful life of the tantalum-coated device. Hamid (90/3297) applied tantalum carbide-coated graphite tubes to the determina- tion of Ga and T1. For T1 the pyrolysis temperature could be increased from 400 to 1000 "C and most of the interferences from inorganic acids were eliminated. A tungsten-coated graphite tube has been used by Zheng and Zhang (911407) to eliminate the interferences from 5000-fold amounts of chlorides for the determination of Li with ammonium nitrate or diammonium hydrogen phos- phate as chemical modifiers.A method for the determina- tion of Li in blood was developed. Nater and Burau (9011 97 1) examined the use of lanthanum- tungsten- and zirconium-treated graphite tubes for the determination of silicon. The zirconium-treated graphite tubes improved the atomization characteristics of Si in the presence of alkali metal fluorides as chemical modifiers and gave the best results. Sensitivity was 50 pg of Si at a confidence interval of 95%. No evidence of silicon carbide formation was observed and over 200 samples could be analysed without any degradation of the zirconium-treated surface as shown by no change in the sensitivity.Pyrzynska (9 1/62) examined the use of electrographite pyrolytic graphite coated electro- graphite tungsten- and zirconium-coated graphite tubes for the determination of Cr. The best results were obtained with pyrolytic graphite coated electrographite. In a novel approach Baxter and Frech (90/3328) applied the amalgam forming properties of Hg with platinum directly in a graphite atomizer. The Hg vapour generated by reduction with tin(@ chloride was swept in a flow of Ar through a platinum-lined graphite atomizer to permit in situ preconcentration. Atomization of the Hg was carried out under gas-stop conditions in order to maximize sensi- tivity. For 50 ml sample volumes of synthetic sea-water detection limits (20) below 2 ng 1-l were obtained.Atnashev (90/3266) reviewed molybdenum and tungsten metal electrothermal atomizers compared with graphite atomizers with and without ballast or platform accessories. Prudnikov (9 1/968) examined the performance of micro- furnaces (0.5-3 mm diameter and 5 mm long) fabricated from graphite tantalum and niobium. Higher sensitivity and reduced interferences were claimed. Nakamura and Kubota (91/11) proposed a method to extend the dynamic range of a calibration graph obtained from a tungsten-strip atomizer by calculating the initial mass of an analyte on the atomizer using an atom formation model. The model is based on the assumption that the rate of atom formation given by a simple Arrhenius-type expression is a function of the number of atoms in a sample on the heater and the heater temperature.To extend the dynamic range further the light beam from the hollow cathode lamp was adjusted so as to pass through a region of low atom density above the heater. Ivanova et al. (91/230) and Khavezov et al. (9 1/234) used the tungsten coil electrothermal atomizer originally proposed by Berndt (J. Anal. At. Spectrom. 1990 5 179R) to determine As Sb and Sn in gold (91/230) and alkali and alkaline earth elements in am- monium paratungstate (9 1/234). The tungsten coil elec- trothermal atomizer was found to tolerate higher concen- trations of chloride ions than conventional graphite elec- trothermal atomizers (91/230) and to be more suitable for the low level determination of Ba Ca and Mg in a carbide forming matrix such as ammonium paratungstate (9 1/234).Welz et al. (9012255 901397 1) continued their scanning electron microscopy studies on surfaces from ETAAS for total pyrolytic graphite (TPG) (9012255) and glassy carbon tubes (90/3971). The inner surface of TPG tubes was found to be fairly rough owing to adhering residues of the polycrystalline electrographite substrate on which the TPG was deposited. These residues were vaporized on subsequent dry heating and recondensed on the tube surface in the form of nodules and flakes but disappeared entirely when the tube was heated with an analyte solu- tion. All the experiments were continued for about 550 atomization cycles and all tubes appeared to be in good condition at that point although the sensitivity for V in dilute HN03 and Mo in iron had decreased by approxi- mately 50%.The signal for P in lanthanum disappeared almost entirely and that for Cu in HC104 was very erratic throughout the experiment. It was not always possible to correlate a change in analytical performance with a vis- ible corrosion pattern. De-lamination exfoliation and pitting were typical types of corrosion and primary faults caused by irregular crystal growth the most likely sites for corrosive attack. However the extent of the corrosion was dependent upon the matrix. Glassy carbon tube surfaces (901397 1) were found to vary depending upon the manufacturing date. Corrosive attack on the surface was found to depend on the matrix and its oxidizing power. High iron and lanthanum concentrations were found to be more corrosive than perchloric acid.A frequent form of attack was the removal of the protective skin which is responsible for the low reactivity of glassy carbon with oxygen followed by penetration into and enlargement of the micropores. Clear evidence was found for catalytic graphitization which gives rise to the forma- tion of intercalation compounds which eventually resulted in preferential oxidation and vaporization of this carbon type. Kitagawa and Tanahashi (901395 1) investigated the atomization behaviour of Co Fe and Ni from metal strip atomizers. The various atomizer metals molybdenum tantalum and tungsten showed different atomization peak profiles. The tantalum strip surface covered with tantalum oxide caused tailing of signal peaks which could be reduced by atomization in an Hz atmosphere owing to reductive reactions however for Co and Ni with a tungsten surface the peaks were exceptionally broad.It was postulated that a solid solution was formed between the analyte atoms and the metal surface.JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 197R 1.2.2. Sample introduction The sheer volume of references received for review and limitations of space preclude any detailed description of many of the procedures described. The reviewer (X.L.S.) of this subject has attempted to select those that show particular novelty or wide applicability and promise for the future. One paper worth consulting is that by Sturgeon (90/2087) where sample introduction was considered from the point of view of analysing marine samples; some pertinent questions regarding the different forms of sample introduction into an electrothermal atomizer are addressed.The perennial topic of calibration in solid sampling was discussed by Baxter and Frech (91/1507) who compared solid sampling with the cup-in-tube technique and a constant temperature two-step electrothermal atomizer. Consistently lower vapour-phase temperatures and greater interferences were found in the former. The use of a convective gas flow during atomization and non-resonance lines as a means of reducing sensitivity were shown to lead to a greater potential for interferences. Non-resonance lines were more sensitive to matrix-induced changes in the temperature interval in which atoms were formed compared with resonance lines.Atsuya et al. (9 1/ 1509) compared three standard materials NXST Tomato Leaves coprecipitations prepared with magnesium oxinate and nickel-dimethylgly- oxime (DMG)- 1 -(2-pyridylazo)-2-naphthol (PAN) as cali- bration standards for solid sampling. Both the NIST and synthetic material prepared from coprecipitation with magnesium oxinate were suitable standard materials for the direct determination of Cu in several biological materials. Low results were obtained using coprecipitations prepared with nickel-DMG-PAN. This same group Akatsuka and Atsuya (90134 13) used a synthetic reference material prepared by coprecipitating cobalt with magnesium(@ 8- quinolinate to determine vitamin BI2 as Co in solid pharmaceutical samples with the cup-in-tube technique. For a sample mass of 1 mg the detection limit for Co was 0.15 pg kg-* (4 pg kg'l of vitamin BIZ).Low and Hsu (91/1510) collected Pb from airborne aerosols on membrane filters and analysed samples from the filters directly with graphite platform boats and Zee- man-effect solid sampling electrothermal atomization. The distribution of Pb between the sub-samples from each filter was generally homogeneous with RSDs of 11-37% but typically t15Oh for samples with 8 h sampling times. Luecker et al. (90/3994) described a combined solid sampling autoprobe system and applied it to the determina- tion of Cd Cu Mn Pb and Zn in biological matrices. A large number of papers and abstracts are now begin- ning to be generated on slurry sampling. Those workers who have been extolling the virtues of this approach to sample introduction in electrothermal atomization for the last few years should feel rewarded that the topic is starting to become more widely accepted.Miller-Ihli (90K 1687 91/C692) discussed the benefits and limitations of an automated ultrasonic agitation system for biological samples including fluids which may contain sediments. The approach provides significant time savings compared with conventional ashing procedures and minimizes the risk of sample contamination and analyte loss prior to analysis. Carnrick et al. (90/3295) described the design and use of a commercially available automated ultrasonic probe sampler accessory which requires no physical modifications to the electrothermal atomizer or solution autosampler. This system was used by Jordan et al.(90/3294) to determine Mn in RMs. Approximately 10 mg of sample were weighed directly into the autosampler cups and 1 ml of a suspending solution containing dilute nitric acid and Triton X-100 added. Owing to the relative high concentra- tions of Mn in the materials the less sensitive 403.1 nm line was used. No chemical modifier or pyrolysis step was used in the electrothermal atomizer programme and results were within the 95% confidence limits of the certificate values. Bradshaw and Slavin (90/C1688 90/2090) described the application of this equipment to the determination of As Pb Se and T1 in coal and fly ash RMs. Detection limits were of the order of 0.5-1.0 pg g-l in the solid sample with precisions ranging from 2- 10% depending upon the amount of solid sample delivered to the atomizer.Schmiedel et al. (90/3414) considered the problems of solid or slurry sampling for the determination of Mo Ru Rh and Pd in radioactive simulated waste samples carried out in glove boxes and hot cells. The slurry technique was preferred; samples were diluted either with a graphite powder or as a direct suspension in a chemical modifier. Recoveries were between 91 and 102% with RSDs of 4-8% for solid and 91-103% with RSDs of 14-20% for slurry sampling respectively. Haraldsen and Pougnet (90/ 1 342) determined Be in coal slurries. The ETA autosampler was modified to allow continuous magnetic stirring of the coal slurry. Aqueous standards were used for calibration with magnesium nitrate as the chemical modifier.Good preci- sion approximately 5% RSD and accuracy were obtained at the 3 pg g-l level. Pyrolysis and chemical modification were found not to be required by Bendicho and de Loos- Vollebregt (9 1 / 195) for the determination of Cu Co Cr Fe Mn and Ni in slumes of glass samples. The same workers used a slurry extraction procedure (9 111 96) for these glass materials. The samples weighed into autosampler cups were suspended in 3% HF and the slurries stirred by passing a flow of Ar through them. The Ar flow achieves effective mixing of the slurry and removes part of the silicon as silicon fluoride. Homogeneous slurries were obtained with- out the use of stabilizing or dispersing agents and calibra- tion was achieved using aqueous standards. Russian workers Kharlamov and Karyakin (901326 l) applied a novel approach of electric spark colloidal disper- sion to produce slurries from monolithic samples of steels and alloys to determine Bi Pb Sb and Sn.A similar method of spark induced ablation and dispersion in water was used by L'vov and Novichikhin (91145). The results for Cu Fe Mg Mn Pb and Zn in high-purity aluminium were in good agreement with certified values. Detection limits were in the range 2-50 ppb. Shengjun and Holcombe (9111550) utilized unicellular green algae to preconcentrate Cu ions from sea-water and river samples; 6 mg of algae were mixed with 10-100 ml of sample. The resultant algae pellet separated by means of a centrifuge was resuspended in 1 ml of OS0h nitric acid and analysed as a slurry by ETAAS. The values determined were within the limits of certification for the RMs SLRS-1 and CASS- 1.The advantages of an air- ashing stage to avoid the build-up of carbonaceous residues following slurry atomization was investigated by Ebdon et al. (9 1/6). Not surprisingly similar results to those using air or O2 ashing in the clinical field were found. Air ashing significantly reduced interferences from non-specific ab- sorption and allowed a wider range of ashing temperatures without sample loss. Chromium Co Mn and Pb were determined in tomato leaves human hair mussel Chlorella and sewage sludge RMs. Good agreement was obtained with the certified values. Nakamara et al. (90/3361) examined over 30 different surfactants as dispersing agents for slurry analysis. Molyb- denum sulphide-aluminium oxide catalyst samples were suspended in an aqueous solution containing triethanolam- ine and nonylphenylpolyoxyether.Marecek and Synek (9 1/845) reported on the determination of Ga in a-alumina powder. The slurry 0.25% m/v was suspended in etha- nol-water (9 + 1). For calibration standard oxides were prepared either with Ga occluded within the alumina matrix or adsorbed on alumina present in the a- or y-forms.198R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRYy AUGUST 199 1 VOL. 6 It was found that alumina decreased markedly the volatility of Ga and increased the sensitivity approximately 8-fold compared with aqueous solutions containing no alumi- nium. This was considered to be owing to the mini-platform effect of the alumina on the atomizer wall. Kane and Epstein (90/C4078) considered the implica- tions of sampling statistics with respect to slurry sampling for the ETAAS analysis of geochemical reference materials.While slurry sampling has a number of advantages for these materials the measurement precision is highly dependent upon a homogeneous analyte distribution in the samples. However they concluded that even in those instances where slurry sampling results in unacceptable inaccuracies mineral speciation information can frequently be postu- lated from the data. In a conference report Welz and Sperling (90/Cl683) asked the relevant question 'Solid and slurry sampling in GFAAS-is it worth the effort?' They reviewed the advantages and disadvantages of both ap- proaches and concluded that for samples that are relatively easily brought into solution slurry sampling is not rec- ommended though for refractory samples such as coal and ash which usually have relatively high trace element concentrations slurry sampling is of real advantage and matrix effects are minimal.Russian workers (90/3047) proposed a method for the determination of As Bi Sb and Se in high purity water by in situ concentration of the hydrides on the inner surface of an electrothermal atomizer. The detection lim- its were 2 0.03 0.05 and 3 pg 1-l for As Bi Sb and Se respectively. Deng and Liang (9 1 / 126 1 ) examined the trapping of hydrides of As Bi Ge Pb Sb and Sn directly in a graphite electrothermal atomizer. Absolute detection limits were in the range 60 pg-2.1 ng with RSDs of the order of 0.35-2.4% but with no indication of the concen- tration range over which these were measured. Sturgeon et al.(90/3393) discussed the efficient trapping of volatile hydrides of As Bi Sb Se and Sn on microgram masses of palladium and other platinum group metals in a graphite electrothermal atomizer. Absorption occurs at relatively low temperatures (200 "C) and analytical figures of merit were improved over hydride trapping on the bare tube wall. Absolute limits of detection (30) ranged from 8 pg (Se) to 43 pg (As). The catalytic reactivity of platinum group metals promotes low-temperature deposition of the hydrides by dissociative chemisorption. Haug and Chon- ghua (90/415 1) compared the direct introduction of aque- ous Ge solutions into a graphite electrothermal atomizer equipped with a pyrolytic graphite L'vov platform using chemical modifiers of palladium nitrate or mixed palla- dium and magnesium nitrates with hydride generation techniques onto a pre-reduced coating of palladium or palladium-magnesium nitrate. The collection temperature was 700-800 "C.Recoveries were of the order of 80-90% with detection limits of 30 pg absolute and 3 ng 1-* relative assuming a 10 ml sample volume for the hydride generator. No conclusions were presented from an analytical point of view concerning the relative merits of the two approaches. Zhang et al. (90/3396) applied their trapping procedure for volatile hydrides on palla- dium discussed last year (J. Anal. At. Spectrom. 1990 5 179R) to the determination of Bi Ge and Te in geologi- cal materials and natural water samples.Astruc et al. (911240) discussed a simplified theory of on-line discontinuous detection in liquid chromatography linked with electrothermal atomization. This theory makes provision for the effects of interface measurement on peak shape. Measurement of peak area was found to be essential as the peak height was sensitive to many parameters. Experimental evidence for the theoretical conclusions were presented for the determination of bu- tyltin species. Baeckstroem and Danielsson (9 1 /252 9 1/1303) described a continuous-flow two-step extraction system linked with an electrothermal atomizer for the concentration and separation of Cd Co Cu Fe Ni and Pb in sea water. In the first step the metals were extracted as dithiocarbamates into Freon 113 and in the second step they were back-extracted into a dilute aque- ous mercury(rr) solution. The sample throughput was 30 h-1 with concentration factors of the order of 50-100-fold and extraction yields in the range 80-107%.Detection limits were less than 10 ng 1-l. The development and potential of coupling FI on-line sorbent preconcentration with electrothermal atomization was discussed in several presentations by Welz and co-workers (9 1/C787 91/1433). It was pointed out that while FI as the name implies handles flowing streams FI preconcentration and matrix separation on solid sorbents is a discontinuous process which fits well with the discrete non-flow through nature of ETAAS. While the loading time is wasted with flow through detectors waiting for elution this time can be fitted perfectly into the cycle time of an electrothermal atomizer programme. Lead was used as a model element (9 1 / 1433) with diethyldithiocarbamate (DDTC) as the chelating agent.The chelate was formed on-line and loaded for 60 s onto a 15 pl conical micro-column of bonded silica with octadecyl functional groups (C18) The column was washed with water and eluted with ethanol into a 75 pl collector prior to introduction into the electrothermal atomizer. A 26-fold enhancement of peak area compared with direct introduction was achieved with a precision of 1.9% RSD for 0.1 pg 1-l of Pb and a detection limit (30) of 0.0003 pg 1-*. The procedure was applied to the determination of Pb in sea-water RMs. The almost complete removal of the matrix allowed measure- ments to be made without chemical modifiers.In view of the many and varied manual preconcentration pro- cedures that are starting to be reported in the literature the potential to automate these methods using on-line FI techniques presents an exciting opportunity for the future. Sneddon (9 1 /64 9 1 / 1 529) examined the precision and accuracy of introducing aqueous solutions of Cd Cu and Mn as dry aerosols by pneumatic nebulization and an electrothermal vaporizer linked to an impaction-electro- thermal atomizer AAS system. The efficiency of the impaction device was assessed (9 1/64). On an uncoated electrographite surface particles < 50 pm were collected and particles >85 pm were not. Increasing the jet-to- impaction distance from 2 to 8 mm improved the collec- tion efficiency of particles >50 pm.Russian workers (9 1/469) examined the problem of increasing the sensitiv- ity of ETAAS to allow the direct sampling of gas-aerosol components in clean rooms and laboratories in the semi- conductor industry. They attempted to decrease losses and increase the residence time of the atomized particles in the gas phase. The most significant factors influencing the localization and confinement of the atoms in the atomizer volume were the direct losses caused by the jet- like wear and diffusion processes as well as chemical losses due to oxidative processes. Chinese workers (91/421) determined Ag in waters by electrolytic precon- centration on a tungsten wire cage-shape multilayer disc electrode prior to introduction of this electrode into an electrothermal atomizer.The detection limit was 0.005 pg 1-l and no interferences were observed in the presence of more than 30 foreign ions. The use of a pyrolytic graphite L'vov platform as a cathodic macro-electrode for the preconcentration of Cd prior to introduction into a graphite tube for conventional atomization discussed in last year's review (J. Anal. At. Spectrom. 1990 5 179R) has now been published (90/3505).JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991 VOL. 6 199R 1.2.3. Fundamental processes A number of the conference reports discussed last year (J. Anal. At. Spectrom. 1990 5 179R) with respect to the use of MS to investigate atomization mechanisms have been published. McAllister (9014 142) showed that gas-phase oxides of As Ga and In may be formed and lost during thermal pre-treatment prior to atomization.Prell et al. (90141 53) studied the real-time mass spectra of gas-phase species in an effort to elucidate the mechanisms controlling vaporization atomization and interferences on Sr by calcium. The results suggest that Sr atoms are produced by desorption of the Sr created by dissociative chemisorption of the oxide. Strontium precursors included the carbide oxide and hydroxide. During atomization Sr was lost by carbide and cyanide formation. The low- and high-tempera- ture carbide losses imply two different formation mecha- nisms. Calcium interferes by increasing low-temperature strontium carbide and hydroxide losses and in shifting the appearance of free Sr to a lower temperature.Hassell and Holcombe (91K757) discussed some of the problems associated with interpreting the mass spectra obtained using secondary ion mass spectrometry (SIMS) to elucidate ETA reaction mechanisms. The signal intensity in SIMS spectra is affected by (z) diffusion (ii) loss to the gas phase (iii) change in analyte morphology and (iv) reactions. These problems can be clarified by use of a cycling temperature programme SIMS technique at varying heating rates. This technique enables one to determine if the reaction is thermally reversible and/or if morphological changes are occurring. Wang et al. (90/3339) studied the atomization mechanism of Cu from a graphite surface with the aid of thermal desorption MS and computer simulations. Results indicated that the desorption of Cu atoms from the graphite surface at individual active sites is the rate-limiting step.Comparing the atomization of Cu metal and Cu oxide powders with aqueous solutions revealed that Cu oxide molecules are dispersed prior to reduction by carbon. The following reactions are proposed for aqueous solutions C~(NO~)~(s)+CuO(ads)~Cu(ads)-~Cu(g) Computer simulations and experimental results indicated that the Cu dimer may form from gas-phase reactions at higher concentrations but that the gaseous dimer is not generated from the graphite surface. L'vov and co-workers have been the most prolific of groups during the period of this review concerning the proposed reduction of oxide by carbides (ROC) mechanism to account for the interaction of metal oxides and carbon within a graphite atomizer.A number of the conference reports mentioned last year (J. Anal At Spectrom. 1990,5 179R) have now been published and are recommended to those readers with an interest in this area of electrothermal atomization research. L'vov (90/209 1) discussed the back- ground to the formation of this mechanism. The mecha- nism is essentially a reduction process based on two concurrent reactions MXO,(S/l) +yC(s)+xM(g) + Yco M(g) + .as)-+MCz(g) MCAg) + (Z/Y)M,O,( S/l)+( 1 + xz/y)M(g) + S O The first of these reactions occurs on the surface of the graphite and the second on that of the oxide. Two assumptions had to be introduced in order to validate this mechanism. Firstly the presence of defects on the graphite surface favouring the formation of excess of gaseous carbides and secondly the assumption that irrespective of the saturated vapour pressure the oxide is reduced via formation of gaseous metal atoms.This mechanism is discussed extensively with respect to the phenomenon of spike formation during the atomization of Al and Mn (90/4141). It was shown that the reduction of Al and Mn oxides by carbon causes a delay in the vaporization of gold and palladium injected separately into the same atomizer. This effect was attributed to the formation of a carbon film on the metal particles of gold and palladium owing to the decomposition of the excess of Al and Mn gaseous carbides formed at the moment of the appearance of the spikes. This effect was observed when mixtures of gold and Mn or palladium and Al were pipetted onto one site as well as onto different sites in the graphite tube (91/216) which in the opinion of these workers tends to confirm the above theory.Bendicho and de Loos-Vollebregt (9 1 / 1 92) examined and characterized the appearance of spikes on the absorption signal of Ai using different sample introduction techniques such as thermospray deposition and suspension and solu- tion introduction. The results were interpreted with respect to the carbothermal reduction of oxides. The distribution of the sample on the surface of the atomizer after drying governs the formation of spikes. L'vov et al. (91/1595) studied the effect of the structure and nature of the distribution of the dry residue of a sample on the formation of absorption signal spikes.Visual observations were made of the change in structure of a dry residue spot of krb203 during carbothermal oxide reduction confirming the simul- taneous occurrence of the process over the entire surface of the sample spot. An increase in the particle size of the sample results in a higher amplitude for the absorption signal spikes and the ROC process becomes continuous for separate Yb203 particles weighing > 10 pg. The gas-phase transfer of metals from a graphite probe to a furnace wall during low-temperature pyrolysis of oxides of Bi Co Cr Cu In Mn Ni and Pb was observed by L'vov et al. (90/3378). The temperatures of the transfers were 400-840 K and agreed well with values calculated for the chemical reduction of oxides by carbon to the metal.The correlation between theoretical and experimental temperatures con- firmed the carbide mechanism of the process. Gilchrist et al. (9 l/C67 1) also studied the vaporization and atomization of Ag As Au Cu Mn Pb Se and Sn from a graphite probe inserted into a constant temperature graphite atomizer. Arsenic Pb Se and Sn were lost in molecular form at temperatures for which no atomic absorption signals were observed. The results for Pb and Sn were consistent with a mechanism where the condensed oxides are vaporized prior to their equilibrium dissociation in the gas phase. Arsenic and Se were rapidly lost from the graphite probe but were found to undergo desorptiodadsorption with the graphite wall prior to their equilibrium dissociation in the gas phase.Silver Au Cu and Mn were found to be atomized directly from the graphite probe surface without the formation of molecules. Katskov and Kopeikin (901 1529) presented experimental results to confirm the validity of an earlier proposed quasi-equilibrium model of metal oxide atomiza- tion in ETAAS. Atomization was found to depend upon the concentration of O2 directly above the sample surface in addition to the temperature and thermodynamic properties of the metal and the oxide. The partial pressure of O2 coming from outside into the boundary layer over the sample the equilibrium pressure of the metal in the boundary layer and the theoretical atomic absorption were determined for a series of oxide decomposition reactions. Russian workers (9 1 /276) reviewed the explosive atomiza- tion of material i.e. spike formation in ETAAS.Fu and Li (9 1/382) investigated the atomization mechanism of Pb in a graphite atomizer using a time-resolved technique. The proposed process involving reduction of the oxide to metallic Pb by carbon on the surface of the graphite tube rather than the thermal decomposition of the oxide in the vapour phase seems to agree with the findings of L'vov. The thermodynamic modelling of processes in electro-200R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 thermal atomizers has also been reviewed by Russian workers (9013265). Gilchrist et al. (90/4143) discussed the gas-phase thermodynamic equilibrium model proposed to account for the shifts in absorbance pulses of As Cr Pb Se Sn and Zn when H2 or CO are added to the Ar purge gas or ascorbic acid to aqueous solutions.The results are consi- dered to be consistent with the hypothesis that the absor- bance pulses are shifted owing to the production of H2 and CO from pyrolysis of the ascorbic acid. The gas-phase dissociation equilibrium of the analyte oxides are disturbed by the addition of H2 CO or C02 to the gas phase. Hydrogen or CO shifts the absorbance pulses to lower appearance temperatures and C02 has the opposite effect. The energetics of desorption of solution and vapour-phase deposited analytes from various graphite surfaces discussed last year (J. Anal. At. Spectrom. 1990 5 179R) has now been published (9115). Lynch et al. (9115) studied the energetics of atomization of Ag Au Cu and Pb in pyrolytic graphite coated uncoated electrographite and glassy carbon tubes following deposition of the analyte as a solution (primary site) and as an aerosol vapour (secondary site).For Cu and Pb an apparent first-order rate of release occurs from all tube types and from both primary- and secondary- deposition sites suggesting that both elements desorb from the surface as individual atoms. Activation energies for Ag and Au were independent of furnace tube type but dependent on the deposition mode. The data from these elements suggest the formation of micro-droplets or caps (primary site) and islands (secondary site) with desorption occurring from the droplet surface or at the metal-graphite interface. Sturgeon et al. (9013393) calculated Arrhenius energies and used them to characterize analyte-substrate interactions for the adsorption of volatile hydrides of As Bi Sb Se and Sn on pg masses of palladium and other platinum group metals (PGMs).The thermal desorption of all analytes from the PGMs was reported to be first order. With respect to the direct analysis of solids or slurries there is little understanding of the chemistry of analyte release and chemical modijication. Jackson and Qiao (901C30 10) considered that when an analyte metal is adsorbed on a refractory particle in a graphite atomizer free atom production can be considered to occur in distinct stages (i) the analyte desorbs (either as the element or some compound) from the particle; (ii) the analyte undergoes gas- heterogeneous- or condensed-phase reactions within the atomizer; and (iii) the analyte is released as atoms. These workers applied the model of McNally and Hol- combe (Anal.Chem. 1987 59 1105) which enables the prediction of the order of analyte release from an examina- tion of the shape of the absorbance-time profile. While no results were presented in the abstract it is to be hoped that this work results in a publication and provides further insight into the chemistry of atomization from slurries. In a series of papers Chinese workers Yan and Lin (9013463 9013588 911381 9111028 9111450) proposed an improve- ment to the Smets method of calculating the rate constant of atom formation (9013588) that avoids the assumption of steady-state first-order kinetics for atom formation and atom loss.They used this improved method to study the atomization process of Al Co Cu Fe and Mo (9111028) and Ag and Na (9111450). Sadly so little information is given in the abstracts from the Chinese journals that it is impossible to say what conclusions were reached. Schron (9011957) discussed the thermodynamic data available concerning gas equilibria chemical reactions in thermal plasmas with regard to their importance in signal interfer- ences in AES AAS or AFS. Thermodynamic calculations covering 42 elements and more than 150 of their halides are included in this report. In general atomization of their halides directly depends on the partial pressure ratio pH21pHX2 (where H = hydrogen and X = halide). The conference report on loss mechanisms discussed last year (J.Anal. At. Spectrom. 1990 5 179R) has now been published (90/3397). In the published paper a theoretical model for the diffusion of analyte species inside a tube atomizer is developed with diffusion considered as the dominant process. The predictions of this model deviate from L'vov's during the initial phase of atomization but the difference disappears in the tail of the pulse. Schwab and Lovett (90/3966) used computer simulations to model the atomic emission signal from graphite furnace atomic emission systems. The excited states were found to be created by absorption of continuum radiation presumably from the tube walls. The time between the absorbance and emission peak maxima was a function solely of the diffusion coefficient of the analyte for a known temperature ramp however questions remain about the temperature dependence of diffusion.Evidence for re-deposition on the graphite surf-ace could be obtained by simulating published absorbance-emission peaks and the position and nature of the emission peak was proposed as a useful tool for graphite furnace diagnostic studies. In a conference report Lovett (9 1/C663) discussed atomization in graphite furnaces and considered the influence of non-uniformity in the atomiza- tion process with the aid of computer simulation. Rademeyer and Vermaak (901C2907) attempted to eluci- date the atomization mechanisms of Si in a graphite atomizer by recording the molecular spectra of gaseous molecular species formed during atomization. No reference spectra could be found in the literature and thermodynamic and kinetic parameters were determined for reactions leading possibly to the formation of oxides and carbides.No actual atomization mechanism is postulated in the abstract. X-ray diffraction and thermodynamic calculations were applied by Jiang et al. (911991) in order to study the atomization mechanism of B and the enhancement of sensitivity produced by a chemical modifier of strontium nitrate. The formation of B atoms is due to the sublimation of solid B derived from the reduction of B203 by carbon. The enhancement of the B signal by SI-(NO~)~ is due to the formation of SrB6 before atomization which decreases the volatilization losses of B206 and retards the formation of B4C. Havezov and Russeva (901291 6) examined the atomi- zation of P from the platform and in the presence of nickel- ( 11) and lanthanum(II1) chemical modifiers by measuring the slopes of the ln(absorbance) versus T-' curves.In both instances the atomization mechanism is considered to be A deteriorated graphite surface could be repaired by treatment with Zr0Cl2. Thermogravimetric and X-ray diffraction techniques were used by Haron et al. (9 1 1 1072) to study the differences in thermal breakdown of hexa- chloroplatinic acid and cis-Pt(NH,),C12. These showed that a solution of H2PtC16 decomposed to yield volatile PtC1 before being converted into metallic Pt. A solution of cis- Pt(NH3)2C12 was converted into metallic Pt in a single step. The differences in the thermal decomposition mechanisms could be one of the reasons for the lower signal obtained from H2PtC1 solutions compared with cis-Pt(NH3),C12 solutions.The appearance temperature of Pt was examined by King et al. (911C794) who found that the form of platinum in the sample affected the appearance tempera- ture. Grigic et al. (9013981) studied the influence of N,N- tetramethylenedithiocarbamate (TMDTC i. e. pyrrolidin- 1-yldithioformate) and tetraethylthiuram disulphide (TETD) on the thermal stability of Hg with X-ray diffrac- tion analysis of the compounds formed. All studies con- firmed in both inert and oxidizing atmospheres the formation of HgS prior to atomization. Radioactive 76A~ was used by Krivan and Arpadjan (9014002) to study the behaviour of As"' and AsV in a graphite ET atomizer. Matrix systems including hydrochloric and nitric acids P2(g)=Wg); P(g)=P*(g)JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL.6 201R sodium chloride urine serum and a tetramethylammon- ium hydroxide solution of hair were examined. Various modifier combinations allowed significant stabilization during thermal pre-treatment but in samples containing chloride the presence of HN03 was necessary to stabilize As"'. The conference report from L'vov concerning the theore- tical calculation of characteristic mass values discussed last year (J. Anal. At. Spectrom. 1990 5 179R) has now been published in English (9111453) and Russian (90/3379). L'vov et al. (9013356) also calculated the coeficients of sensitivity losses (2) for the analytical lines of 19 elements when using Zeeman-effect background correction.Calcula- tions were performed without allowing for the emission line width and taking the Doppler profile into consideration. The algorithm was used to calculate the Voigt integral and the hyperfine structure of the lines was taken into account. The coefficients of sensitivity losses for Ca Be Li and Mg lines were dependent on the emission linewidth of the light source. The determined experimental values for the major- ity of lines exceeded the known available values however good agreement between the calculated values and those obtained experimentally by these workers was found. Guo (9OlC2045) used the characteristic masses (m,) to determine Cd and Pb in biological matrices by absolute analysis (ie. without standards). The methods were carefully optimized and STPF conditions applied but the abstract is confusing as to which conditions were critical to enable standardless analyses to be achieved.Frech and Baxter (91/1458) in the published paper derived from the conference report dis- cussed last year (J. Anal. At. Spectrom. 1990 5 179R) considered the temperature dependence of atomization efficiencies in graphite atomizers. The atomization effici- ency (eat) defined as 1 00(m,[calc]/rn,[exp]) was calculated for a spatially and temporally isothermal two-step atomizer for the following elements Ag Al Au Bi Cd Ga Ge In Mn Pb Se Sn Te and T1. For some elements comparative measurements were made with a Massmann-type atomizer operated under STPF conditions. The elements Al Au Ga Ge In Mn Se Sn and Te were found to have temperature dependent atomization eficiencies and are thus susceptible to forming stable volatile compounds at lower atomization temperatures. Improved atomization efficiencies were found for some of these elements when a pre-atomization cool-down step was incorporated into the temperature programme using the Massmann-type atomizer.Generally the results with the two-step atomizer verified the validity of the method and the fundamental constants used to calculate the theoretical m values. The workers demon- strated that comparing characteristic mass values is not a valid method of comparing different atomizer designs and argue that a better criterion for evaluating atomizer performance is atomization efficiency although they clearly stated that from a practical analytical viewpoint detection limit performance is far more important than the characteristic mass.This paper is recommended to those readers interested in this topic for its clarity and style of presentation. These workers are to be congratulated for including an extensive appendix which discusses in some detail many of the underlying factors involved in deriving and calculating theoretical characteristic mass values. Us- ing an alternative approach Zhou and Yan (91/1146) calculated theoretically the coefficient /3 between numbers of ground-state atoms and the peak height absorbance in a GTA-95 atomizer. They compared these theoretical charac- teristic mass values with the values given by the manufac- turer to assess atomization efficiency. For volatile elements such as Cd and Zn the efficiency was found to be greater than 80% 20-50% for medium volatile elements such as Ag Cr Cu Mg and Ni and less than 1Ooh for less volatile elements such as Al Ti and V.Harnly (90lC2994) performed Fourier transforms of transient electrothermal atomizer absorbance-time profiles of species in order to yield the amplitude and phase angle arrays. The amplitude array was found to be concentration dependent while use of the phase angles from the lowest frequencies was an extremely sensitive indicator of subtle changes in the position and shape of the furnace signals. Applying principle component analysis to the phase angle arrays enabled changes to be observed between samples as a function of the type and strength of the acid matrix presence of an interfering agent and age of the graphite atomizer.The summation of ETAAS signals was applied by Berndt and Schaldach (91/236) to increase the detection limits so that there was no need for prior separation or preconcentration. The accuracy of the results obtained were confirmed by separation and preconcentration. Wegsche- ider et al. (9111252) reduced the raw data from ETAAS absorbance-time profiles to eight descriptors and applied a fractional factorial design method to derive empirical models useful in the prediction of sensitivity from single atomization curves. The models were applied to assess the interferences on Rh Se and Sn. The prediction of sensitivi- ties from the typical changes in peak shapes due to frequently encountered interferents such as aluminium chromium iron magnesium sodium and zinc were gener- ally within 5-1 5% relative error.1.2.4. Interferences Electrothermal atomization has been commercially avail- able for 20 years and is an area of research starting to suffer from the 're-inventing the wheel' syndrome. Nowhere is this more pronounced than in the examination of interferences and chemical modifiers. This reviewer has to voice concern at some of the work accepted for publication. The responsi- bility for this situation lies not solely with the authors but also with the referees of papers for scientific journals. A criterion for a scientific publication is that of originality and sadly this criterion is being overlooked rather too often. While palladium in all its various forms continues to dominate the field there are many areas and elements that require different chemical modifiers. The potential of vanadium(v) proposed by Tsalev et al.and discussed last year (J. Anal. At. Spectrom. 1990 5 179R) has now been published (90/4 1 45). Kelemen et al. (9 1 /844) examined molybdate vanadate and molybdovanadate as chemical modifiers for Ba. These ions form complexes with interfer- ing phosphate and silicate ions and carbides. This last effect may improve the sensitivity for Ba by suppressing the interactions between Ba and graphite. A combined V205-Si modifier was employed by Bishop (90/3347) to determine Ba in sea-water. This combined chemical modifier aided injection sample drying graphite tube lifetime and elimi- nated most of the sea-water components in a slow pyrolysis at 1 150-1 200 "C.With atomization at 2600 "C and a gas flow rate of 60 ml min-' the characteristic mass was 5.6 pg per 0.0044 A s and the detection limit (la) was 2.5 pg in a 25 pl sample. For sea-waters with a Ba concentration of 5.6-28 pg l-l precision was 1-2% and accuracy 2-3%. Work on phosphate modifiers continues to generate large numbers of papers especially in the clinical field where these modifiers do not suffer from the precipitation prob- lems that palladium based chemical modifiers can have. Subramanian (90/2233) examined mixtures of 5 g 1-l (NH4)2HP04 + 0.4 g 1-l (NHJ2Cr2O7 + 2% v/v HN03 and 50 g 1-l ascorbic acid+0.2 g 1-l iron as iron(n1) nitrate as possible chemical modifiers for the determination of Sn in aqueous leachates from copper pipes soldered with lead-tin (NH&HP04 + 0.5 g 1-' Mg(NOj)2 + 0.2% V/V HN03,2 g 1-'202R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL.6 solder. The first chemical modifier was preferred based on its higher sensitivity and thermal stability. The detection limits were 1.7 and 12.8 pg 1-l for absorbance and integrated absorbance measurements respectively. It is not clear from the paper why a palladium based chemical modifier which is generally recommended for Sn was not included in the study. Yet the paper is recommended as one where the sheer volume of analytical data presented leaves no doubt that the method is reliable and robust. A whole collection of reports from various workers (9 1/250 90/C2 100 9 1/422 90/337 1) discussed the use of phosphate modifiers with and without 0 ashing for the determination of Cd and Pb in whole blood and other biological matrices.Nothing that has not already been published for over ten years is presented in these papers. Huang et al. (90/3474) found that the use of ascorbic acid overcame an interference from iron on the determination of Cr in soil samples after acid digestion with HN03 HF and HC104. For the determination of V Bauza et al. (90/C294 1) claimed that ascorbic acid increased the thermal stability of the V signal with a pyrolysis temperature of 600 "C but depressed the peak height sensitivity. This depression could be overcome by adding ammonium sulphate. A group of Chinese workes proposed the use of calcium nitrate as a chemical modifier for A1 (91/169) B (90/C2048) Be (91/165) Dy (90/C2048) Ge and Sn (91/181).In all instances calcium nitrate was claimed to increase the thermal stability of the analyte enhance sensitivity allow lower atomization temperatures and reduce interferences. The use of alkali metal fluorides as chemical modifiers was examined by Nater et al. (90/3330 90/1971) for the determination of A1 (9013330) and Si (90/1971). An HF-CsF mixture was used for A1 to form AlF3 which sublimes at 129 1 "C. The subsequent gas-phase atomization of AlF3 occurred rapidly and produced sharp clean peaks. The use of CuF was also examined and appeared to eliminate interferences from organic acids but at the expense of shortened tube lifetimes. For Si an HF-LiF mixture was employed. Conversely Wu et al.(91/918) discussed the interference of fluoride on the determination of Al Ca and heavy metal ions in environmental samples. The choice of chemical modifier and electrothermal atomization conditions for the determination of A1 is still a popular topic. Quinonero et al. (90/325 1) found increased sensitivity for A1 when using Mg(N03) instead of NH4H2P04. The paper by Redfield and Frech (90/2056) accounting for the pre-atomization losses of A1 was dis- cussed last year (J. Anal. At. Spectrom. 1990 5 179R). However when a laboratory with over 11 years experience of determining A1 in serum (91/C753) is still refining the method clearly the chemistry of A1 in a graphite electro- thermal atomizer is still open to discussion. Cunningham et al. (91lC753) found a narrow plateau in the ashing profile around 1400 "C with a considerable reduction in sensitivity for temperatures of less than 1300 "C. The variation between different tubes could move the signal off this plateau. Magnesium nitrate did not change the shape of the profile but 1% v/v HN03 did produce a flatter ashing profile.Triton X-100 was found to cause a reduction in peak and integrated absorbance for aqueous standards but not for serum samples. This effect was to some extent overcome by the addition of KN03 to the standards but the investigators were still not satisfied with the minor daily differences shown between KN03 and serum based standards. The interference of indium in the atomization of Ag Bi Cd Sn and TI in the presence of hydrobromic acid was investigated by Yudelevich et al.(90/2228) with the aid of a two-step atomizer. The results indicated that the indium interference is due to the formation of InBr which leads to a higher bromine concentration in the gas phase thus shifting the reaction equilibrium towards the formation of metal bromides. These bromides are removed from the observation volume by diffusion before their dissociation is complete. Several different chemical modifiers have been proposed for a variety of elements during the last year. Aluminium nitrate was proposed for Be (91/49) in the presence of HF and HN03. For the determination of Bi (9 1/289) cadmium and lead improved the sensitivity palladium impaired sensitivity and cobalt molybdenum and zinc produced double peaks. Several different modi- fiers were tested for B (91/C805) but none overcame the memory effects associated with this element and all showed a similar level of performance. The best sensitivity was obtained with calcium chloride.The matrix interference of iron(Ir1) on Cr was overcome by pneumatic nebulization into the graphite atomizer (90/3513). The mechanism of interference was claimed to be a physical process resulting from the 'occlusion' effect of iron(1Ir). The different degrees of interference of carbon black on the atomization of Al(OH)3 and A1203 (9 1 /7 1 7) and iron oxides (9 1/ 1 127) were exploited by Yoshimura and Huzino (9 1/717 9 1/1127) in order to allow the differential determination of the various species. The matrix effect of boron on the determination of Fe (90/3416) in primary circuit cooling of a nuclear power plant was investigated.Styris and Prell (91/C672) used MS to investigate the possible mechanisms of action of magnesium nickel and palladium chemical modifiers. Modification of the analyte vaporization behaviour was shown to be due to interfer- ences in the formation of low temperature gas-phase oxides hydroxides carbides and polymers of the analyte. The principal mechanisms involve homogeneous condensed phase reactions. These workers stated that a clearer under- standing of chemical modifier mechanisms is required in order to advance their use further. Sakurada et al. (90/4020) examined the mechanism of stabilization of Pb with a palladium chloride chemical modifier using X-ray photo- electron spectroscopy.Lead as lead chloride in the presence of palladium chloride was reduced to a metallic form at 200 "C and remained at 600 "C after all the chlorine had been removed. The action of the modifier was discussed in terms of Pb reduction and alloy formation with palladium. The application of reduced palladium was discussed by Schra- der and Beach (91/C674). While they claimed that there is substantial evidence that reduced palladium is the neces- sary intermediate species to achieve optimum analyte stabilization there is also a large body of evidence that shows that unreduced palladium also works extremely well. There is a need in this area for a thorough investigation of the mechanisms of palladium chemical modification. Erard (9 1 / 1066) examined a variety of chemical mod~ers for the determination of Se in cereals with Zeeman-effect background correction.The palladium and magnesium combination was the most suitable for wheat samples containing approximately 1.0 pg 1-1 of Se but for those containing 0.1 pg 1-' the modifier was unsuitable because of double atomization peaks that were thought to be due to poor atomization cloud uniformity. Chinese workers (9111 70) claimed that a mixed chemical modifier of ammo- nia solution and palladium increased the sensitivity of determinations for As Cd Cu and Pb. From the abstract it appears that ammonia solution was added to the strong acid (HzSO4) sample solutions to form ammonium salts prior to the addition of the palladium. Bozsai and Karpati (9 1/286) discussed the high sulphate interferences on As and Se in mineral waters.This paper is obviously the precursor of the conference abstract discussed last year (J. Anal. At. Spec- trom. 1990 5 179R) and a fuller investigation of the interference has now been published (9 1 /7 1). Sampson (9 1/C8 14) discussed the use of a mixedpalladium-platinum chemical modifier for the determination of As and Se inJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 203R biological materials containing phosphate and iron using continuum source background correction. The platinum catalyses the reduction of phosphate and retards the atomization of iron thereby reducing the interferences but has a depressive effect on the sensitivity which can be retained by the addition of palladium. However this method is not completely foolproof as shown by the statement that integrated absorbance was subject to a residual interference which did not affect peak absorbance.The action of platinum in combination with CO to reduce the spectral interference from iron on the determina- tion of Se was discussed last year by Peile et al. (see J. Anal. At. Spectrom. 1990 5 179R) and resulted in correspon- dence between Radziuk et al. and Peile et al. (91/849). Radziuk et af. (9 11849) considered that the effects claimed for CO are due solely to the presence of platinum although Peile et al. (911849) believe that a more complex mecha- nism is involved than a simple temporal separation of iron from Se. Martin and Williams (90/2057) found that a combined chemical modifier of palladium and copper nitrates with an H2-Ar purge gas allowed the determination of Se in microwave digests of bovine liver against aqueous standards.This method was developed for bovine liver as this was considered to be a more complex tissue sample than the heart tissue which was to be analysed in a further study. Interested readers are referred to the paper by Fairhurst et al. (Fairhurst J. Lloyd B. and Delves H. T. Anal. Chim. Acta 1987 97 197) which discussed the acid digestion of heart tissue for Se determinations. In a tungsten atomizer copper was found by Fudagawa and Kawase (911936) to be the most suitable chemical modifier to prevent losses of Se. The thermal stability of As was assessed by Krivan and Arpadjan (9014002) using radioactive isotopes and for a variety of chemical modifiers including nickel molyb- denum palladium and tungsten.Palladium was also exam- ined in mixtures with hydrogen peroxide. No conclusions were given in the abstract as to which was the preferred chemical modifier. Subramanian (9013 5 53) directly deter- mined As in urine with platform atomization and a chemical modifier of either palladium or palladium plus ascorbic acid. Smeyers-Verbeke et al. (91/846) found that a chemical modifier of 6 pg of palladium nitrate in combina- tion with 500 pg of ammonium nitrate allowed the direct determination of Cd in undiluted urine against aqueous standards. This is a lower amount of palladium than the 50 pg recommended earlier by Yin et al. for the determination of Cd in biological materials (Yin X.Schlemmer G. and Welz B. Anal Chem. 1987,59 1462). However Smeyers- Verbeke et al. (911846) claimed that the use of a large amount of palladium should be avoided in order to reduce the background absorbance due to sodium chloride. Although palladium and/or magnesium nitrate are excel- lent chemical modifiers contamination of the modifier with the analyte element of interest can cause severe problems for determinations at very low levels. Bulska et af. (9014 148) found that for the determination of Cd in serum the endogeneous Cd contamination in the palladium-mag- nesium nitrate modifier could be removed by pre-injecting the modifier and heating to 1100 "C. After cooling the sample was injected and a maximum pyrolysis temperature of 800 "C applied. The very features that are an advantage for the use of palladium or other metals as chemical modifiers can cause problems when one has to determine elements in a matrix of palladium or platinum.Popova and Bratinova (9013482) described the determination of Pb in diaminodichloropalladium and diaminodinitropalladium. Thermal analysis X-ray diffraction and infrared spectro- metry indicated that the decomposition process takes place at 356 "C for diaminodichloropalladium and at 222 "C for diaminodinitropalladium with the principal product of this process being metallic palladium. No reducing agent was required in order to produce metallic palladium. Arpadjan et al. (90/4 146) discussed the determination of Ag Cd Co Fe Ir Ni Mn Pb Rh and Ru in pure platinum and palladium. Three groups (9013332 90/4150 911474) have investi- gated the interference of chloride matrices on the determina- tion of Mn.Stobbaerts and Deelstra (911474) found that interferences from KCl and NaCl in foods and biological materials could be overcome by using a suppressor such as L-ascorbic acid. In contrast to many other published observations they claimed that contamination of samples during preparation is negligible. Hulanicki et al. (9014 1 50) found that a chemical modifier consisting of an acidic component (phosphoric acid) and a basic component (calcium ions) combined with platform atomization im- proved the accuracy of Mn determinations in the presence of inorganic salts. While the use of the platform alone improves the determination chemical modification com- bined with platform atomization had the greatest effect.Pressurized atomization in Ar at 304 kPa was employed by Fazakas and Zugravescu (9 1/59) for the determination of Pb in the presence of 0.1-5% NaCl. The depression of the Pb signal was not observed at this pressure and the effect was ascribed to a longer residence time in the atomizer due to pressurized atomization producing a higher vapour temperature and therefore better dissociation of molecular compounds. In a conference report Fisher et al. (911C779) discussed the use of reducing gases as gaseous chemical modifiers for the determination of V and Al. Problems were encountered by Temminghoff (90/4 1 58) in the determina- tion of Cd in digested plant material with a modifier of 1% NH4H2P04 0.2% Mg(N03)2 and 0.04% AlC13.Automati- cally pipetting the sample solutions followed by the modi- fier produced double peaks due to problems with the air gap between the two solutions on the platform. The failure of the solutions to mix and the presence of an air bubble caused sputtering during drying and double peaks from wall and platform atomization. This problem was solved by adding 5% v/v butanol as a surfactant to the modifier solution. This allowed the solutions to flow and mix on the platform and produced single peaks. Dittrich and Fuchs (9012060) used a chemical modifier of lanthanum ions to stabilize the phosphate ion for the determination of P by FANES and mofecular non-thermal excitation spectrometry (MONES) (9013483) of the PO and HPO species. With FANES a detection limit of 90 pg was achieved which is an improvement of approximately 60- fold compared with conventional commercially available ETAAS equipment.Ajayi et al. (9012229) compared the temperature gradients and chemical interferences on Cd Mn and Pb for one normal and two modified tubes. A higher vapour temperature and lower chemical interfer- ences from magnesium and sodium chlorides were ob- served when the tube temperature gradient was reversed through a reduction in the wall thickness towards the ends of the tube. However these signals show more noise as a result of the greater emission continuum from the ends of the tubes which may well have a deleterious effect on detection limits. 1.2.5. Developments in technique Multi-element analysis using ETAAS is an area that was previously the preserve of a few specialized research groups throughout the world but interest is increasing and several novel approaches besides the established but not widely used continuum source atomic absorption spectrometry (CSAAS) are starting to find their way into the literature.In a conference report Harnly (911C743) touched upon the Achilles heel of multi-element techniques with a title that204R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1 99 1 VOL. 6 included the phrase 'the search for photons in the UV'. Both CSAAS and ETAES suffer from poor detection limits at wavelengths lower than 280 nm compared with conven- tional ETAAS. Several improvements have been suggested such as pulsing the continuum source detection with a linear photodiode array (PCS-LPDA) and hollow anodes or cathodes with the FANES technique.All three approaches have detection limits comparable to ETAAS and are compatible with multi-element determinations. The appli- cation of CSAAS to the analysis of biological materials was discussed by Miller-Ihli (9012 199 9013584). Various sam- ple preparation methods were used for ETA including direct analysis wet ashing dry ashing and slurries. The use of compromise atomization conditions did not appear to limit significantly the accuracy and precision and good agreement was found with RMs. Moulton et al. (901C3033 9013499) discussed in more detail the modifications to a PCS-LPDA-CSAAS system and wins the prize for the longest acronym in this year's review. With flame atomiza- tion LPDA detection resulted in an improvement in the signal-to-noise ratios by a factor of 3-9-6.2 for the Cd Co Fe Ni and Zn resonance lines between 2 13.9 and 248.3 nm.A pulsed source in conjunction with LPDA improved the signal-to-noise ratios by a factor of 5.8-8.5. Two Russian workers (9011520 9013412) appear to have developed a multi-element ETAAS system using a continuum source and separation of the elements as volatile compounds. In order to solve the problems of sample introduction and atomization the elements were isolated as volatile com- pounds followed by gas-chromatographic separation. The separated compounds were fed individually into the atom- izer in a stream of inert gas. This technique appears to be applicable to non-dispersive modes of AE AF and AA using non-selective detection. A fast sequential ETAAS instrument has been described by Batie et al.(901C3014). With this new design it is claimed that up to 24 elements can be determined in a single sample in rapid sequence. The application of this instrument coupled with a glow-discharge atomizer to the determination of powders was described by Carter et al. (90/C3012) and by Bernhard et al. (90/C3013) to the determination of titanium and nickel based alloys. Taga et al. (9013362) proposed a simultaneous ETAAS system dedicated to the determination of Ag and Cu. The reso- nance radiation from Ag (328.07 nm) and Cu (327.40 nm) hollow cathode lamps were introduced through the same spectral bandpass of the monochromator. When the mixed radiation was passed through the atomizer two peaks corresponding to Ag and Cu appeared in the absorbance- time profile.The addition of palladium or platinum improved the separation of the peaks without mutual interference and by measuring the peak heights the simulta- neous determination of Ag and Cu could be achieved. A single-channel time-divided simultaneous multi-element AAS system was described by Nakamura and Kubota (9012 196). A multi-element hollow multi-cathode lamp for Al Cu and Fe was used with a tungsten strip atomizer and no monochromator. The power to the three cathodes was supplied in the order Cu A1 and Fe. Consequently the emission beam for each element has the same light path but occurs in a distinct time sequence. By forming suitable volatile molecular species in an ETA non-metallic elements can be measured.Gomez et al. (90/3508) evaluated ET molecular absorption spectrometry for the determination of fluorine in biological samples after mineralization and from the same group Corvillo et al. (91/1585) applied this method to the determination of fluoride in sea-water. Aluminium monofluoride is formed in a graphite atomizer and the molecular absorption at 227.45 nm was measured. The interference by chloride was removed by adding a chemical modifier of NH4N03 with 0.01 mol dm-3 Al+O.Ol mol dm-3 Sr. In sea-water the detection limit was 8-10 ng ml-1 with a peak height precision of 5-7% for 0.2 ,ug I-' of F-. Yu and Huang (901C2037) determined Br by measuring the molecular absorbance due to InBr at 248.3 nm with radiation from a chromium lamp in an electrothermal atomizer.A graphite platform greatly reduced the background due to I n 0 and increased the signal-to-noise ratio 1 0-fold. The difficulties of determining chlorine and bromine by FANES were discussed by Dittrich et al. (90/C315 1). The presence of easily ionizable elements such as potassium and sodium changes the electronic pressure of the helium discharge which affects the intensity of the atom and ion lines. Naumann et al. (9013398) applied comprehensive fluctuation analysis to the investigation of the compromise conditions required by the FANES source. These showed that the optical conductance of the spectrometer has to be improved especially for wavelengths t 2 10 nm in order to exploit the potential detection power of FANES fully.In a series of reports Harnly et al. (90/C3036,90/C3 149 9013498) outlined the operation of a FANES system with the furnace QS a hollow anode (HA-FANES). The cathode is a carbon rod which runs down the centre of the atomizer. This arrangement results in a discharge with excellent stability and no need for electrical shielding. The emission signals were dependent on the current density and viewing position with more intense signals obtained when viewing from the top and left of the discharge. The detection limits for Cd and Cu were 0.8 and 1.5 pg respectively which are comparable to those obtained with conventional FANES. Yizai and Harrison (901C2049) proposed a tungsten loop furnace (WLF) coupled with a hollow cathode discharge (HCD) and AES which is much simpler to build and operate than the FANES system.The technique was applied to the determination of B in glass at a concentration of approxi- mately 0.04 mg 1-' with a precision of (5%. Chakrabarti et al. (9013348) proposed a new analytical technique of pulsed and transient modes of atomization using a commercially available cathodic spluttering atom- izer. The transient mode uses a high-power discharge for the rapid production of analyte atoms whereas the pulsed mode uses a discharge of much shorter duration and higher power to achieve even faster atomization. The faster kinetics of atom formation result in better sensitivity than for steady-state atomization. The sensitivity of the tech- nique is sometimes similar to or greater than that of ETAAS but no analytical results are presented in the abstract.The preliminary analytical characteristics of furnace atomization plasma excitation spectrometry (FAPES) for Ag were presented by Blades and co-workers (901C3083 9013975 911C662). A detection limit (30) of 0.3 pg was achieved. This source combines the high transport effici- ency characteristic of a graphite electrothermal atomizer with the powerful excitation characteristics associated with a high temperature plasma gas. The source has been improved from that originally described by using an isothermal integrated contact cuvette (9 1/C662). Hadeishi and Le Vay (9111508) described the construc- tion of stable long lasting high intensity discharge lamps operated at high frequency between a few hundred Hz and 150 kHz that were used to excite the spectra of refractory elements by utilizing their halides. The lamps are small enough to fit between the poles of a magnet and conse- quently can be used in the direct analysis of solids by Zeeman-effect AAS. A multiple mode laser diode was employed by Ng et al.(9111548) as the line source for ETAAS. Several emission lines are supplied from a single diode with a line width narrower than the absorption profile. The separation between the lines was approximately 0.3 nm. These characteristics are beneficial for simulta- neous background correction and peak ratio measurements.JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 205R The detection limit for Li in 10 pl sample volumes was 0.6 pg l-l which is comparable to that obtained from hollow cathode ETAAS systems.The linear dynamic range was approximately two orders of magnitude. Butcher et al. (90lC303 1) presented the first use of a commercial graphite furnace and probe atomizer with laser-enhanced ionization (LEI). Laser-enhanced ionization uses a tunable laser source to excite atoms to an energy level near the ionization continuum while a d.c. electric field is applied across the atom cell (see also section 3). After excitation a fraction of the atoms ionize generating electrons and positively charged ions. The electrons move in the electric field to the cathode and generate a current that is the signal used to determine elements by LEI. The sample on the probe was inserted into the graphite atomizer after a constant temper- ature had been reached with the aim that atomization under near isothermal conditions should minimize gas-phase reactions between the analyte and its matrix.The potential of the method was evaluated by the analysis of biological RMs. A multichannel background correction technique for pulsed laser-excited atomic fluorescence spectrometry with ETA (ET-LEAFS) was described by Sjostrom (90/4156). A detection limit of 0.05 pg of Ga in aqueous solution was obtained for the corrected signal. It was shown that black- body radiation scattered laser light and molecular fluores- cence can be corrected for by the simultaneous background correction technique. McCaffrey and Michel (9 1 / 1 5 33) applied capacitive-discharge heating to a small anisotropic graphite tube which provided heating rates of up to 65 "C ms-l with a final temperature of 2500 "C.Preliminary investigations with Pb indicated that sample deposition on the unbroken lamellar graphitic planes provided about 1.5 times the peak area and peak height sensitivity obtained from sample deposition across the lamellar planes. The vapour from a graphite ETA was introduced through the anode tube into a magnetron rotating d.c. arc for AES measurements by Slinkman and Sacks (9111 547). This ensured adequate sample-plasma interaction and produced AES detection limits for Cd Cr Cu Fe Mg Mn and Zn in the ppb range. Kitagawa et al. (90/3331) described a novel approach to separate the atomic vapours of Cd Hg and Pb prior to AA measurements. The method consists of a separative column atomizer (SCA) which is an alumina tube packed with graphite granules coated with gold or platinum or mixed with tin and heated to 800-1400 "C.Different retention characteristics and peak broadening were observed for different packings. These workers claimed that retention of the vapour through the SCA might be useful for the separation of co-existing elements and removal of their interferences. No analytical results were presented in the abstract. Forsyth (91/258) described the optimization of a combined gas chromatographic-AAS system equipped with a quartz tube atomizer for organotin determinations. The atomizer was heated at 800 "C with a 60% H2-40% air gas mixture the calculated detection limits (30) were 7.3 pg of Sn as Me3BuSn 8.2 pg of Sn as Me2Bu2Sn 16.6 pg of Sn as MeBu3Sn and 17.2 pg of Sn as Bu,Sn.Haug (91/54) overcame the problems of poor reproduci- bility in a commercial automatic sampler system for ETAAS by continuous de-gassing of the dispenser rinse solution. This resulted in improved performance by avoid- ing the development of gas bubbles in the dispenser syringe. Brueggemeyer and Fricke (90/C303 5) discussed the possi- bility of increasing the dynamic range in ETAAS by using more of the information contained in the atomic peak profiles. Because the deviations from linearity become more pronounced as the absorbance increases the upper points on the peak may be reduced in size while the points at lower levels (the leading and trailing edges) remain largely unaffected. Hence it is possible to calibrate using selected parts of the peaks with a variety of options such as partial peak area point by point regression analysis dAldt compar- isons and multivariate pattern recognition techniques.The only drawback to this procedure is the need for both the sample and standard peaks to have the same temporal position and a similar shape however the workers claim that this can be overcome by using for the standard a known amount of analyte in the sample matrix of interest. A number of workers continue to investigate the possibil- ities of reducing the length of ETA programmes. Zugra- vescu and Fazakas (9 111 392) found the maximum pyrolysis temperature for Ag in carbonated mineral waters to be inadequate and nebulized the samples directly into the graphite tube at 150 "C followed by atomization without any pyrolysis step. The detection limit was 1.5-3 pg with a precision of 2-3%.The pyrolysis step was removed and the drying step optimized by Hinds et al. (90lC1684) for the determination of Pb in soil slurries. This reduced the ETA cycle time from 160 to 40 s. Analysis of a high carbon content soil showed good Pb recoveries even when no modifier (normally a palladium-magnesium nitrate mix- ture) was used. By making alterations in the software and firmware controlling the autosampler Slavin et af. (90/2089) developed fast STPF methods for several ele- ments in over ten different RMs. Total cycle times including autosampler washing and sample uptake were less than 60 s. As a chemical modifier and the pyrolysis step were omitted the background signals were larger and use of Zeeman-effect background correction was usually required although continuum source background correction was not tried.Bradshaw and Slavin (90/2090) used fast sampling STPF conditions with Zeeman-effect background correc- tion to determine As Pb Se and T1 in coal and fly ash slurries. The slurries were prepared automatically by ultrasonic mixing and the ETA programmes omitted the pyrolysis step and chemical modification. With a cycle time of approximately 60 s and calibration against aqueous standards reasonable agreement was obtained with the certificate values for the SRM materials examined. Hinds (91/C675) found that for the determination of trace elements in precious metals fast atomizer programmes were possible.The inclusion of a chemical modifier and pyrolysis step was unnecessary owing to the chemical modifier action of the matrix metals for volatile analytes. Shuttler and co-workers (90/C30 1 1 9 l/C688 9 ~ C 7 8 9 ) discussed a range of tests that can be used as quality assurance (QA) procedures to test instrument performance. The determination of Pb in sodium sulphate (90/C3011) illustrated the differences in performance of different platform systems and how well STPF conditions were achieved. The performance of a previously proposed QA procedure (Slavin W. Manning D. C. and Carnrick G. R. Talanta 1989,36 17 1) was examined in an interlabora- tory exercise (91/C789). This allowed an assessment of the stability of ETAAS instruments and performance of differ- ent platform designs in a wide variety of laboratories.1.3. Chemical Vapour Generation This section will present developments in the understand- ing instrumentation and technique of chemical vapour generation as used in conjunction with AAS detection. Applications to specific analyses of which there are many particularly environmental and biological samples and to systems employing AFS and AES detection will be reported in other ASU reviews. In a new development as an alternative to the detection of free analyte atoms hydrides of the analyte have been absorbed in chromogenic solutions and determined by UV-visible molecular absorption spec- trometry (Ge 91/88; and As and Ge 911440).206R ,JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 1.3.1. Hydride generation Fundamental studies of chemical interferences in the liquid phase occurring during the generation of metal hydrides have been undertaken since the early 1970s notably by Smith (Analyst 1975 100 300).It was concluded that 'before this type of accessory [hydride generation (HG)] for AA for the determination of As Bi Ge Sb Se Sn or Te is used it is necessary to ensure that the matrix being analysed does not interfere'. Any analyst new to HG would be well advised to consult Smith's paper along with more recent work dealing with specific elements and matrices. Sanz and co-workers (91/1435 911C1788) have carried out an in- depth study of the interference of iron and mercury in the determination of Sb both experimentally and by means of a computerized speciation model. They observed that in a variety of acidic media as the iron concentration (<0.1 mol 1-l) increased initially there was no reduction in the AAS signal for Sb; at higher concentrations the signal decreased with increasing iron to a level (>0.3 mol 1-l) above which the signal was again independent of iron concentration.With mercury however there was no interference at concentrations up to approximately 0.5 mol 1-l. The difference in the effect of iron and mercury was attributed to the formation of complexes in the reacting solution whereby the actual redox potential of the Fell1 -Fell system was higher than that of the Sbv-SblI1 system while that of Hgl1 -Hg was lower. Gas-phase interferences by arsenic and selenium in the determination of Te have been overcome by preferentially vaporizing arsenic in the presence of Br2-H2S0 and reducing Se to a non-interfering state with KI (90K4083); other interferents were removed by precipitation with lanthanum hydroxide.The mechanisms whereby hydrides decompose into free atoms are not fully understood. It has been suggested (9 1/168) that in an electrically heated quartz cell atomization of some hydrides is not solely a gas-phase process but that the cell surface also plays a part. The atomization of Ge from GeH in an electrically heated quartz tube was studied by Bing et al. (9 1/C2 139) and found to be different from that of ASH or SeH,. At temperatures below 960 K most of the GeH decomposed on the surface of the tube above that temperature O2 in the gas entering the tube caused serious interference by the formation of GeO.Based on a theoretical model Quingle et al. (91K2140) confirmed the conclusion of Welz and Melcher (Analyst 1983 108 213) that the essence of thermal decomposition of arsine is a free radical process with turning points in the atomization efficiency when the concentration ratios of H2 and O2 are 1 :2 and 2 1. General studies of interferences included one on the metal ion enhancement of the rate of hydrolysis of sodium tetrahydroborate in an acetate buffer at pH 5.0. This effect has consequences for the timing of operations in the determination of As"' (90/1164) by both manual and continuous flow methods. Interferences in the determina- tion of Bi by nickel cobalt and copper were found (9111 74) to arise in the liquid phase while those by antimony lead and selenium occurred in the gas phase.The latter effect was overcome by heating the intake tube of the quartz atomizer and the former by addition of 8-hydroxyquinol- ine and thiourea. The effects of 26 interfering species on the determination of As and Se were examined by Castillo et al. (90/ 1227). They found widespread interference the extent of which was greater when a flame rather than a quartz tube was used for atomization. The interference of copper and nickel in the determination of As and Se has been studied in depth by Janssen (90/ 19 10). Correction by standard addi- tions was found to be problematical. When the matrix composition is not known determination by ETAAS was recommended. Preconcentration and reduction of interfer- ence effects was achieved by extraction of As and Se with dioctyltin dinitrate solution in CHCl and butanol (91/1034).The elements were stripped from the extract with 2 mol dm- hydrochloric acid prior to determination by HG-AAS. The detection limits for As and Se were 0.4 and 0.8 ng ml-l respectively. The determination of Pb in samples frequently requires pre-oxidation; potassium hexa- cyanoferrate(II1) (91/180) or nitroso-R salt (9111970) have been recommended as oxidants to be followed by oxalic acid (9 1 / 1 80) and ammonium cerium nitrate (901C2044 9 1 / 1496) as interference suppressing agents. In order to determine total Sn in organotin compounds it was neces- sary to treat the compounds with bromine in carbon tetrachloride (90/3484); the hydride generating solution contained approximately 1.2% water in DMF.Atomization was in an electrically heated quartz tube and the detection limit was 1.5 ng ml-l. A volatile species of Cd presumed to be the hydride has been generated by carrying out the reaction with sodium tetrahydroborate in DMF in the presence of diethyldithiocarbamate (90/ 1 994). The detec- tion limit was 9.1 ng of Cd. The interference of selenium and tellurium on the cold vapour determination of Hg was used as the basis of an indirect method for the determina- tion of Se and Te (90/3049) and gave detection limits of the order of 1 x with a relative error of 10% in the determination of 0.2 pg of Se or Te. Minor modijications to discrete sample processing systems for hydride generation have been found to give worthwhile improvements in performance.A commercially available hydride generation cell was modified to facilitate sample and reagent introduction and washout without removal of the cell and interruption of the Ar supply to the HS- entrained air flame (90lC2877). The modification speeded routine analysis. Xuan and Chen (91/131) reduced the sample volume required for an analysis from 5-25 ml to 20 pl by mounting a micro-cup inside the HG cell and injecting sample and reagents into it. The absorption signal was measured in a heated quartz micro-cell. The need for a carrier gas in an HG system was overcome (911348) by adding sodium hydrogen carbonate to the sample solution prior to generation of the hydrides in order to prevent explosion.The detection limits for As Bi and Sb were 7 14 and 5 ng respectively. When a 'long-seam' (slotted quartz tube) quartz atomizer was used (91/448) for the determina- tion of Sn with an N2-H2-entrained air flame gas phase interference by e.g. antimony arsenic and selenium was much smaller than when an electrically heated quartz tube was employed; the usable acid concentration range was also greater. The sensitivity was 0.64 ng ml-l per 1% ab- sorption and the RSD 4.9%. The sensitivity of discrete systems can be improved by collecting the generated hydride in a cold trap (liquid air cooled) followed by its rapid release into the atomizing cell. This approach was used in the determination of Ge in iron meteorites (911241) and gave a detection limit of 0.03 pg g-l in the original meteorite.Flow injection is one of the most convenient ways of mechanizing sample handling in HG systems. In addition it reduces sample and reagent consumption can lower detection limits and speeds analysis (90/C2982). Flow systems can facilitate elaborate sample pre-treatment prior to the generation of the volatile compound. Selenium hydride generation usually takes place in acidified samples. The range of acceptable sample pH has been widened to neutral and alkaline solutions by adding sodium tetrahydro- borate before acidifying the solution with hydrochloric acid (91/C746 91/2549). Marshall (911457) has described three variations of u basic manifold whereby interferences in HG may be eliminated. In one system pre-reduction with potassium iodide was used in the determination of elements present in207R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL.6 several oxidation states (see also 91/48). This may also be used as a means for speciation of for example As (9 1/1380) by adjustment of the pH of the sample. In another interferences by noble metals during the determination of As Bi Sb and Se were reduced by the addition of tellurium. Finally interferents in the determination of As and Se were removed by means of an in-line ion-exchange column (see also 9 1/C776). General matrix related interferences were overcome by means of automation of the standard additions process. In-line ion-exchange columns were used for analyte preconcentration in the determination of Bi and Se at ultratrace levels in natural waters (9 1/1076 91/2653).Bismuth was extracted on chelating ion exchangers CPG- 8Q and Se on anion exchanger D-201; both were eluted with 1 mol dm-3 hydrochloric acid directly into the HG system. Detection limits were 1 ng 1-l of Bi and 2 ng 1-l of Se. Separation of the gaseous hydride from the liquid stream is a key step in achieving the best results from FI-HG-AAS. Three designs of gas-liquid phase separators have been examined (91/C774) viz. a glass U-tube a silicon rubber tubular membrane and a PTFE sheet membrane. All were found to be satisfactory for the determination of As in a water CRM (IAEAN-4). The membrane separators gave dry uncontaminated gas streams; the sheet membrane had the shortest rise and memory times. A PTFE sheet membrane was also found to be satisfactory (901351 1) for the determination of Bi in NIST SRM 361 Special Low Alloy Steel AISI 4340 a leaded gun metal and BCS CRM 347 Electronic Flowsolder the detection limit was 0.17 ng of Bi.Stibine was generated electrochemically in a thin layer electrolytic cell using FI and a microporous PTFE tube was used to separate the gas from the liquid carrier stream prior to transfer into an N2 stream for AA measurement in a heated quartz tube (90/C2035). It was claimed that the system suffered from less interference and contamination and was fast and convenient. The application of the system to the determination of As has also been investigated (9K2137). Interferences from Cull SeIV and Hg2+ were observed but could be reduced by the use of appropriate electrode materials.The elimination of Hg2 + interference on the determination of As required the removal of the former by chelation with thiourea and vitamin C. From time to time graphite furnaces have been used as the atomizing cells in HG-AAS. When operated in a constant flow mode at 1800-2300 "C the sensitivities for As Sb and Se were similar to those obtained by conven- tional quartz tube (91/233). Tin however was strongly adsorbed on the graphite inlet tube. A 1000-fold excess of arsenic antimony bismuth selenium tellurium and tin as interfering elements produced no more than a 12% depres- sion of the signal. Reactions between water and H2 and heated graphite gave rise to an increased background. Greater sensitivity can be achieved by collecting the analyte element in the furnace prior to atomization in order to generate a transient signal. The collection of As Bi Sb Se or Sn may be either as the hydride at a relatively low temperature 200 "C (90/3393) or as the element after thermal decomposition of the hydride at a higher tempera- ture 800 "C (9013047 90/4 15 1).Detection limits were in the range 10-40 pg. Hydride collection was effected by means of adsorption directly on the graphite surface or chemisorption on a palladium or other platinum group element coating deposited on the graphite furnace wall [Bi Ge and Te (90/3396 91/Cl858)]. Detection limits ranged from 8 pg for Se to 43 pg for As (90/3393). The higher temperature collection of the elements on the untreated graphite inner surface of the furnace gave detection limits for As Bi Sb and Se in high-purity water of 2.0,0.03 0.05 and 3.0 ng ml-l respectively. Germanium was collected at 800 "C on a platform or graphite foil treated with a palladium-magnesium modifier (90/4 15 1).The reproduci- bility of the determination was 2% RSD with a detection limit of 30 pg ('3 ng 1-l) in the hydride generating solution. 1.3.2. Preparation-separation of volatile organometallic compounds for chemical vapour AAS The use of volatile phases can in some instances greatly enhance the eficiency of sample introduction. In a wide ranging study Castillo et al. (90/C2945 9 1/C 1779) exam- ined the utility of chelates as the volatile phase in analytical atomic spectrometry. The compounds synthesized were acetylacetonates of Al Cr Cu Fe Mn Ni and Zn; trifluoroacetylacetonates of Al Co Cr Cr and Fe; hexa- fluoroacetylacetonates of Co and Fe; and dithiocarbamates of Co and Cu.The compounds were synthesized in an FI system collected on a sintered glass filter which could be heated to the sublimation temperature of the chelate (=250 "C) and carried in a nitrogen gas flow into a heated silica atomization tube for determination by AAS. Chromatographic separation prior to determination by AAS may be used either for speciation of organometallic compounds present in the sample or as a means of separating organometallic compounds synthesized during the sample pre-treatment from an interfering matrix. This approach has been proposed by Rigin (9013412) as a basis for dispersionless and multi-element analysis using non- selective detection. Speciation of organotin compounds in water was effected by extracting the compound into pentane as diethyldithiocarbamate complexes (901342 1).After drying under reduced pressure the complexes were derivatized to form pentylated alkyltin compounds that were separated by GC and determined by quartz furnace AAS. Detection limits were 0.1-0.4 ng of Sn for the various organotin species. High-performance liquid chromato- graphy has been used to separate alkyllead compounds (90/ 1 990) and anion-exchange chromatography to separate biogenic organoarsenic compounds (90/C30 1 6). In both instances post-column treatment of the emuent was neces- sary before determination by AAS could be carried out. Ionic alkyllead compounds were separated in a flow system as their tetramethylenedithiocarbamate complexes ethy- lated purged from the reaction mixture and volatilized into a quartz tube furnace; detection limits approached 0.1 ng. Organoarsenical compounds were photo-oxidized on-line with low intensity mercury lamp irradiation (maxi- mum=254 nm) to arsenate and fed to a continuous flow arsine generator.Sample streams were mixed with potas- sium persulphate in sodium hydroxide solution prior to entering the photoreactor for 20 s. Arsine was extracted from the reaction mixture through a Teflon membrane. The detection limit was 5 ng ('50 ppb). Tetramethyl-and tetraethyllead in petrol were separated and determined by selective volatilization of the sample ( 10-50 pl) in a special reactor at a temperature of 1 50- 180 "C directly into an FAAS system (901 1 174).The detection limit was 3.0 ng of Pb. Tin and organotin species were selectively reduced at pH 2 to their corresponding volatile hydrides (90/1504). The hydrides were collected in a liquid nitrogen cooled trap from which they were fractionally volatilized into an Ar-H,-entrained air flame for the determination of Sn by AAS. The detection limit was 0.3 ng and the RSD was =2.5%. Methylmercury in aqueous samples has been determined by reaction with sodium tetraethylborate in order to convert the non-volatile monoe- thylmercury into gaseous methylethylmercury (9 1/892). The methylethylmercury was then thermally desorbed from the column and analysed by cryogenic gas chromatography with cold vapour AFS.The method also allowed the simultaneous determination of labile Hg" species through208R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 the formation of diethylmercury and of dimethylmercury which was not ethylated. The detection limit for methyl- mercury was 0.6 pg (= 0.003 ng 1-l) for a 200 ml sample. 1.3.3. Mercury by cold vapour generation Three methods of cold vapour AAS viz. batch FI continuous flow all with or without amalgamation were evaluated by Welz and Schubert-Jacobs (90/C205 5 ) with respect to sensitivity freedom from interferences cost speed and ease of operation. The batch system was the most sensitive but suffered from the greatest interference was the slowest and used the most reagent. Flow injection was the fastest used least reagent and suffered least interference but owing to the small sample volume was the least sensitive.Continuous flow with collection of Hg by amalga- mation combined the freedom from interference and ease of operation of the FI system with larger sample volumes to give a method well suited for determining Hg at the 0.1 pg 1-l level. In a series of papers Daniels and Wigfield reported a detailed examination of the determination of Hg by a cold vapour method. They considered reagent volume optimization (9 1 /259) acidic versus alkaline reduction (9 1/260) signal reporting options (9 1/26 1) and instrumen- tal adjustments leading to increased sensitivity (9 1 /262). Particular attention was given to studying the effects of pH and of cysteine on the reduction procedures; the feasibility of speciating Hg in these sulphydryl-complexed and free forms was demonstrated.A number of modest changes in technique that have led to worthwhile improvements in performance in particular circumstances have been reported. For example following oxidation of the sample with 0.4 mol dm-3 H2S04 and reduction with SnCl the Hg vapour generated was flushed out of the reaction vessel by injection of water (91/2496). The gas was dried by passage through a condenser; a detection limit of 0.001 ppb was achieved. The detection limit in the determination of Hg by cold vapour generation was significantly lowered when the Hg vapour generated by tin(@ chloride reduction was collected on platinum (90/3328) or gold (90/2231) in a graphite furnace and subsequently atomized by raising the furnace temperature under gas stop conditions. Using 50 ml samples detection limits were of the order of 0.1 ng 1-l.In some circumstances Hg may be directly extracted from aqueous or gaseous samples by amalgamation on a column filled with HAuC1,- modified packing material (9 11903). The Hg was released by heating and determined by cold vapour AFS. The detection limit was 4 x g. The thermal desorption behaviour of metallic Hg and some organomercury compounds from a gold column was studied by Baeyans and Leermakers (90/1989). They found that the proportion of the Hg released from its different compounds was determined by the temperature dependence of the decomposition process and diffusion of Hg in gold metal. Under optimum conditions of temperature and carrier gas recoveries ranged from 100% for metallic Hg to 80% for methylmercury chloride.A calibration procedure for the determination of Hg by CVAAS in conjunction with collector preconcentration has been described (9 1/25 13). A special valve linked a closed Hg-saturated gas flow with an open flow of the carrier gas to the AA spectrometer. By this means defined volumes of Hg-saturated gas were injected into the system and consequently the problems of contami- nation and loss associated with manual methods were avoided. In the region of 1 ng of Hg within-run precision was better than 1 Yo day to day precision better than 2% and results for various biological RMs agreed with the given values. Wigfield (9 1/C687) quantified adsorption losses in the connecting tube of cold vapour generating apparatus for 1 1 types of tubing.Losses as great as 40% were observed for tubing 30 cm long with 5 mm id. at a flow rate of 500 ml min-l. Munaf et al. (9013046) found that matrix interference by anions cations and organic compounds in the determina- tion of Hg was much reduced when a continuous microflow system with tin(@ chloride in sodium hydroxide solution as the reducing reagent was used. In more recent work (91/C1697) the same system was used with sodium borohydride in sodium hydroxide solution as the reducing agent sodium peroxodisulphate as the oxidizing agent and cadmium chloride as the catalyst; the detection limit was 0.15 pg 1-l. The system was applied to the continuous monitoring of Hg in waste water.From a study of reaction time and matrix effects Ngim et al. (9011949) found that interference effects in the microdetermination of Hg in undigested biological samples could be considerably re- duced and peak height sensitivity increased by using a reaction mixing time of 1 min before bubbling with carrier gas in order to liberate the Hg. Reagent consumption was also significantly reduced. The interference of silver in the determination of Hg can be severe because silver ions may be preferentially reduced to the metal by the reagents and the metal itself can block the release of Hg vapour by amalgamation. Although FI methods reduce the problem the use of a masking agent thiourea or increased acid concentration was recommended (9 1/C 1857) when silver is present in considerable excess. The interference of I - in the determination of Hg was used as the basis of an indirect method for the determination of I- (90/1286).A known and excess amount of Hg2+ was added to the sample to form a stable complex with I-. The free Hg2+ was reduced to Hg with a nitrogen containing sulphate which did not react with the complex. The liberated uncomplexed Hg was then determined by AAS. The recovery of I- from water samples was 92- 1 OOOh. 1.4. Spectrometers 1.4.1. Light sources Hieftje (9 1 / 1 5 1 7) has made a critical comparison of sources and detection methods and there has been one comprehen- sive review with 156 references (90/3322) on theory production and operation of EDLs as light sources in atomic spectroscopy. There is also a review (91/1086) on the use of a continuous wave tunable dye laser in high resolution atomic spectroscopy.The advantage of such devices is that they eliminate Doppler widths of spectral lines. The replacement of hollow cathode sources by compact and inexpensive tunable semi-conductor diode lasers was discussed at length by Hergenroeder and Niemax (9 1 / 12 10). It was claimed that 60% of the elements now measured by conventional AAS could be determined with such lasers if the second harmonic wavelengths generated in non-linear crystals are included. High intensity arc lamps have been described by O’Haver et al. (91X767) specifically for continuum source AAS (see section 1.4.5) and by Zander et al. (90/1974) for general purposes. The latter operating with Ar achieves its improved luminance by special electrode design.Angus et al. (90/C1814) showed that enhanced emission from an HCL can be achieved by the addition of a small amount of N2 to the normal fill gas. Work is still proceeding on the establishment of electron densities and temperatures. The growth of radiation inten- sity with time (‘temporal evolution’) of a pulsed HCL has been investigated by Griffin (911C1952) and the processes of evaporation and excitation using different metals in the hollow cathode have been examined by Mierzwa (91/C2112). From discussions on the characteristics of two Russian types of HCL for AA analysis (911340) it appears that theJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRYy AUGUST 199 1 VOL. 6 209R strong self-absorption observed in one type over a particu- lar range of currents is not observed in the other.Construc- tional differences are not detailed and the reasons for such variations in performance are therefore not clear. Complet- ing a series of studies on the influence of rotating magnetic fie& on an HCL discharge the effects of rotation perpendi- cular to the hollow cathode axis have now been described (90/2258). The radiative properties of the discharge varied with field strength fill gas discharge current and the cathode element although it is said that effects on the line intensities of analytes were generally small. The behaviour particularly ionic:atomic line intensity ratios and current-voltage dependence of low and high voltage internal anode HCL discharges have been investi- gated by Phillips et al.(9111452). Of all the noble gases Ne provides the highest intensity of Cu I 324.7 nm in both high and low voltage versions. As a secondary radiometric standard in space applications a Pt-Ne HCL has been investigated (9 1 17 1 6). This produces a uniform distribution of lines over the range 11 5-350 nm. 1.4.2. Optics An equation which more rigorously treats the phenomenon of stray light has been derived from Beer’s Law (9 113 1) and the parameters derived from fits of the equation to AA data allow quantitative measurement of the proportion of stray light in a particular AA experiment. It has been re- discovered (901C2885) that the measuring range in AA can be extended by ‘manipulating the angles of the burner head with respect to the HC beam’.Rotation of the burner head was often used 20 years ago and the burner stem of at least one early commercial instrument was calibrated in degrees for this purpose. Two papers referred to improvements in gratings. Coma aberration of conventional holographic grating (where fringes are generated using plain and spherical wavefronts) are largely eliminated if the fringes are generated using aspherical wavefronts as reflected from a spherical mirror. It was claimed (9012267) that resolution and energy throughput are both improved. Varied line space (VLS) gratings which substantially improve imaging in grazing incidence spectrometers cannot be made using holographic techniques. It has been shown however (9 117 12) that VLS and holographic gratings can be made to approximate to each other in an imaging sense to the lowest order and that they are therefore interchangeable although the groove profiles may be different.The use of optical waveguides in the development of both AAS and AES techniques was reviewed and discussed by Bauner and de Laffolie (9 111 064). 1.4.3. Detectors A new generation of charge transfer devices (901C2957) provides a range of very high performance detectors from single element replacements for the PMT to arrays with some millions of detector elements. The use of unique read- out modes destructive and non-destructive read-out rapid scan etc. make these particularly attractive in the develop- ment of new methodology in the atomic spectroscopy field. 1.4.4. Background correction de Loos-Vollebregt pointed out (911C2117) that when in Zeeman-effect background correction the a.c.magnetic field is parallel to the optical axis (i.e. ‘longitudinal’ field) no polarizer is required and therefore loss of half the primary source intensity is avoided. In recent work a C-type longitudinal magnet (strength 8 kG at 100 Hz) was used with a transverse heated integrated contact tube. The dynamic range of Zeeman analytical curves can be extended by a factor of about five by changing the shape of the magnetic field so that intensity measurements can be made at three different field strengths (zero intermediate and high) giving additional curves of reduced slope. The limitations of presently available background correction systems using continuum source or inverse a.c.Zeeman effect were enumerated by Schlemmer (9 11C2 1 18). A new system based on the platform work of Frech and the transverse heated tube with longitudinal a.c. Zeeman egect as described by de Loos-Vollebregt (see above) is said to give improved light throughput and detection limits and to be ‘Perkin-Elmer’s contributions to the next decade of graphite furnace analysis’. Arriaga and Stephens (9013954) detected structured inter- ferences from extraneous absorption lines which lie close to the analyte line of interest in a.c. Zeeman-effect background corrected AAS by harmonic analysis of the signals obtained. Calculations were performed based on a model using normal Zeeman splitting and measurements made for the iron-platinum interference at 217.9 nm and the interfer- ence between the isotopes of lithium at 670.8 nm.The analysis showed that the amplitudes of the harmonic frequencies vary with the position and half-width of the interfering line. It appeared that even two lines of identical profile and centre frequency which overlap completely could still be distinguished provided that they did not show the same Zeeman multiplet. Amplitude ratios could serve as a parameter to detect the occurrence of such interfer- ences over a limited concentration range and provide an instrumental method of warning that errors may have occurred in the measurements. The paper discussing the influence of furnace radiation on Zeeman AAS signals discussed last year (J. Anal. At. Spectrom. 1990 5 179R) has now been published (9014 1 44).Li (901C2950) examined molecular spectra produced by Co-NaC1 Fe-NaC1 Ni-NaC1 and Se-Fe systems in a continuum source background corrected ETAAS instrument. Examples of insufficient good and overcorrection were found. For the Ni-NaC1 system the 232.0 nm Ni line is adjacent to the 234.2 nm maximum absorption band of NaCl and the non-symmetry of the absorption band causes overcompensation. These workers considered that the Se-Fe system is similar to Ni-NaC1 and proposed that the over-compensation seen with this system is due to the molecular absorption of FeCl. Yet as Martinsen et al. have shown this over-compensation is most probably due to iron atomic line absorption (Martinsen I. Radziuk B. and Thomassen Y. J. Anal. At. Spectrom. 1988 3 1013). 1 A.5. Continuum source and simultaneous multi-element AAS Work has continued on CSAAS since the earliest papers of O’Haver (ARAAS 1979 9 41) principally in the Univer- sities of Maryland (901C1773 901C1775 9011997 901C3033 9013499 9 1K767 9 1K1988) and Florida (901 199 1 9013982).The wavelength modulating systems of the original instruments have latterly been replaced by photodiode arrays and this is the part of the system which differs the most between these two laboratories. The array used in Florida provides a range of 2.5 nm per line with an acquisition time for a single spectrum of 22 ms. Since last years review when the use of a graphite furnace was reported the air-C2H2 flame (9011991) and ICP (9013982) have all been employed as the atom source. Maryland’s 128- or even 256-pixel array gives a range of 0.2-0.4 nm and an acquisition time of less than 5 ms is possible with a fast data system. Also associated with the latter laboratory is a new pulsed xenon arc lamp (911C767) giving a peak intensity of 260 times normal when operated at 200 A and210R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL.6 resulting in improvements in a signal-to-noise ratio (and therefore by implication also in detection limit) by factors of 6-8.5 for Co Fe and Zn. Considerations for minimum noise levels with this type of system have been set out separately (901C1775) and patents have been applied for (91/1421). O’Haver (911C1861) has also shown that im- proved signal-to-noise ratios result when the spectral width of the light source is comparable to that of the absorption line (instead of much less as required by Beer’s Law) and has discussed the implications for CSAA.Harnly (911C1882) pointed out that with diode array detectors read-out noise rather than diode shot-noise adversely affects detection limits. Shot noise can be made dominant again if source intensity is increased or if a spectrometer with improved light throughput can be employed e.g. a low- resolution monochromator may offer a 25-fold improve- ment over an Cchelle. The use of both line and continuum sources in simulta- neous AA spectrometers has been discussed by Golloch (9 11 1 193). In the former case HCLs were coupled withfibre optics and the monochromator was replaced by a polychro- mator with a wide entrance slit. The performance of this assembly was said to be comparable to that of a conven- tional AA instrument.Multi-element AAS using a continuum source and a wavelength-modulated kchelle polychromator was described by Miller-Ihli (9013584) who gave details of a prototype instrument being used for graphite furnace analyses of biological materials. An kchelle spectrometer in conjunction with a charge injection device has also been used to achieve multiplex detection with continuum source and electrother- mal atomization (9 1 11 549). Absorbances were computed by scanning through all orders of the Cchelle spectrum. Two simultaneous AA spectrometers using conventional light sources have been described by manufacturers. A Hitachi instrument (911245 1) with graphite furnace and Zeeman-effect background correction uses four hollow cathodes and four ‘independent gratings’ in what is pre- sumed to be a static system.Good performance is claimed for As Pb Sb and Se. A dynamic system from Thermo Jarrell Ash (911C2096) is capable of measuring two ele- ments at a time by ETA and four by FAAS. Rapid drives for both wavelength and source selection are synchronized. The entire wavelength range from 185 to 900 nm can be covered in 20 ms so that more than one wavelength and light source can be monitored during even a fast transient ETA signal. 1.5. Instrument Control and Data Processing 1.5.1. Instrument control The requirement for more efficient and rapid methods of analysis has led to the development of a number of sequential systems for FAAS. In one such design (90x30 1 5 ) the analysis of up to 24 elements in a single sample has been reported in a 4 s per element cycle.All elemental and flame conditions were controlled by a computer which also captured stored and reported calibration and sample data. In addition it was possible to change flame conditions automatically from air-C2H2 to N20-C2H2 if required. In one of the new commercial designs rapid galvanometer drives have been employed to perform simultaneous multi- element analysis (9 11C1865). In this instance one galvano- meter drive oscillated an HCL selector mirror capable of alternating the direction of light from each of four lamps many times per second. The lamps up to a total of eight were configured in two tiers on a vertically adjusted dual focal array.Synchronized with the lamp selection mecha- nism a second galvanometer drive oscillated a grating between the corresponding wavelengths. All parameters of the spectrometer optical furnace atomizer autosampler and preparation station were programmed using an external personal computer equipped with trademark software. This software has also been used for the simultaneous determi- nation of element pairs (As-Se and Pb-TI) in soils and waters (90/C3041). The speed of the system is optimized using three characteristics firstly two elements are mea- sured in a single atomization secondly the sample drying stage is eliminated through the use of aerosol deposition and finally sample preparation including chemical modifi- cation is not only automated but is carried out during the furnace cycle and therefore without increasing the analysis time. Following standardization a set of quality control samples are automatically run to verify both the calibration and the method.At each point decision making software determines the next action. Once verification is complete samples are prepared and run along with a single recovery sample for each. Recoveries are calculated and reported for each sample. Sample data are saved to disk only after a successful verification has been performed otherwise the calibration and verification are repeated along with the sample batch. In another commercial design 12 elements per minute have been determined (90/C3013) although the system also uses non-thermal atomization for the analysis of undissolved solid samples (901C30 14).This system uses the integral computer to monitor the internal standard to improve accuracy and a correction known as Pamiers method to calculate concentration ratios. Automated systems for the routine application of ETAAS have also been described. In one such system based on an IBM-AT computer features included automated dilution when the calibration range was exceeded; automated correc- tion throughout the run when standard sensitivity or baseline drift occurred; a novel sample blocking mode; automated recognition of spiked blanks unspiked and spiked samples reference samples standards and sample blanks; programmability to include the order in which solutions (samples modifiers blanks etc.) were picked up by the autosampler; the ability to perform automated digestions in the furnace using a separate digestion solution such as nitric acid; the ability to perform a tube treatment prior to each atomization using a separate treatment solution; and the ability of the autosampler to prepare standards in autosampler cups from a stock solution (911C1949).The last of these features was reported to provide better accuracy than existing commercial systems due to the larger volumes used. A computer controlled apparatus for on-line element preconcentration for FAAS has been described (9 1 /C 1 8 1 6). The system permits the pre-selection of any enrichment factors for each sample the print-out of the preconcentra- tion protocol the automatic element enrichment of up to 20 samples and off-line or on-line operation with AAS. The elements Al Cd Co Cu Fe Ga Mn Ni Pb V and Zn could be enriched from various sample materials and volatile hydrides of As Sb Se and Sn could also be produced. An automated on-line column preconcentration technique for FI-AAS has also been developed which enables enrichment factors of between 90- and 180-fold for seven elements at a sampling rate of 13 h-l (9011948).A second report (9112563) described the automation of an FI system for the hydride generation of Se and subsequent determination by AAS. Pre-treatment of the sample and the details of the automated equipment were reviewed. An automated solid sampling analysis system consisting of a powder sampler an integrated microbalance a transport and handling system for the sample boat a microcontroll- ing unit for all necessary steps and an appropriate AAS instrument has been described (9111 506) and its potential for routine metal determinations discussed.A novel design of Cchelle polychromator has been used to develop a flexible bench top multi-element analyser. Radia- tion at 120 wavelengths was transferred by optical fibres toJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 I VOL. 6 21 1R a bank of photomultiplier tubes. Up to 15 wavelengths could be monitored simultaneously and the instrument programmed to make rapid measurements at up to 60 wavelengths without alteration of the optical fibre selection (9 1/C766). The instrument was equipped with wavelength- modulation background correction facilities which permit operation in simultaneous multi-element analysis mode by continuum source AAS or ETAAS.All procedures in this system are controlled by a microcomputer with programs written in Pascal and pre-compiled at execution. Steady- state or transient signals at different wavelengths could be displayed simultaneously on the computer screen. Peak height and peak area measurements for analyte and background signals are produced for each channel and the data processing facilities are compatible with commercial spreadsheet packages. 1.5.2. Data processing A number of publications have dealt with the use of microprocessors for calibration. In one such paper the principle of piecewise fitting of a curve to a calibration graph was discussed with the aid of both a BASIC computer program and a flow diagram for a programmable calculator (9 111 525).A method for evaluating procedures for approxi- mation of calibration graphs has also been reported (9013388). Six approximation methods as used by major companies producing AAS instruments were evaluated using a model representation of the real absorbance minus the concentration dependence. It was clear from the results of this study however that the function which proved best for approximation over a wide range of real calibration graph characteristics using three reference solutions was not necessarily the best function to use when there was a much more limited change in the characteristics. A compar- ison of least squares and least mean squares techniques in AAS has also been made to investigate the problem of outliers in calibration (9 1/26 10).The factors contributing to the optical limitations in AAS have been reviewed (91/1012). An equation to correct the effects of these limitations was proposed where Ad and A are the measured and the corrected absorbances (xI12)E is the full half width of the geometrical slit (xIl2)* is the full half width of a profile of full foot with xl c is the concentration of an absorbing layer of effective thickness 1 and a is a factor given by a=( 1 +a2/ln2)4 where a is the classical damping factor. The equation is reported to extend not only the linear part of the calibration graph but also modulate its slope. A method for estimating the collisional widths of atomic absorption lines in atmospheric pressure flames (see section 1.1) has been reported by O'Haver et al.(90/3399). The method is based on the shapes of calibration graphs formed from absorbances determined by fitting a computer model to transmission profiles measured with a continuum source. A measurement precision of f 0.1 pm was reported for elements Cd (228.80 nm) to Sr (460.73 nm) using a spectrometer with a spectral bandpass of approximately 5- 12 pm. The application of a multi-curve calibration technique in AAS has been used for the determination of 6Li and 'Li isotopes (9111043). Because of the non-linearity of the calibration graph the results obtained proved unsatisfactory with regular calibra- tion methods and so a series of standards were divided into several segments and a series of calibration graphs fitted to quadratic equations.The optimum calibration graph for a specific sample is selected based on computer computation. Finally although log-log plots are commonly found in the literature their mis-use and mis-interpretation can lead to incorrect conclusions for example about the linear dynamic range of a calibration. The mathematical and statistical implications of such transformations have been discussed (9 1 /C682) using examples from atomic spectroscopy. Methods for the estimation of random errors and detec- tion limits have been the subject of a review with 20 references (9 111 5 15). A comparison was made between theoretical and experimental detection limits for FAAS based on instrumental standard deviation and non-instru- mental errors. A number of publications have also concen- trated on quality assurance programmes.Although in the past many such studies have been based on controlling large scale routine analysis an approach for controlling the quality of a modest number of analytical results has been discussed (91K1529). In addition a number of more specific applications of quality control such as commercial software packages for ETAAS data (9 l/C1832) quality control schemes for geochemical data (90/4043,90/C4057) reference sample data bases (90/C4100) and soil and vegetation analysis (90/C4060) have been reported. In another such paper dealing with quality control procedures for monitoring whole blood and plasma trace metal levels by AAS (91/1088) a number of methods were discussed in detail. These included the use of SRMs and in-house standards for calibration Levey-Jennings charts West- gard's multi-rule quality control schemes and additional information obtainable from cumulative sum charts in order to detect analytical drift from the mean and standard deviation index or z-score plots to show analytical bias.The general application of computers in data processing has been the subject of several publications particularly where automatic processing of results by computer facili- tates a shortening of analysis time increases the infonna- tion content or improves the accuracy of results (9 1/ 1074 90/ 1 5 16). The transfer and manipulation of atomic absorp- tion data into third-party software has also been widely reported (90/C1826 9011 932 90/C2869). The implementation of fast Fourier transforms via the use of residue factored look-up tables has also been investigated (90/1976).The principles of factored look-up tables were reviewed and a gate-level pipelined adder architecture presented. The basics of the quadratic residue system was also discussed. Advanced ways of handling laboratory data interchange and storage problems such as the Analytical Data Interchange and Storage Standards (ADISS) project have also been reported (90K2938). Monte Carlo procedures have been used to study the effects of activation energy and frequency factors in ETAAS (91K1745). Signal summation has been used for the improvement of performance and an increase in the amount of sample in the direct AAS analysis of solids (9 1/2506). Time-resolved AAS signals of several individually weighed solid samples were stored and later summed by personal computer to yield a signal covering all the individual samples with an S / N which was improved according to the Ni law.This made it possible to detect low concentrations in a number of samples without the need for preliminary preconcentration steps. The distributions of trace elements in powdered samples has also been the subject of a statistical treatment (9K1824). Here it was found that the distributions are frequently asymmetric occasionally with several maxima resulting from a small mass fraction with a high analyte content. Statistical treatment using the Poisson distribution has important consequences in for example the prepara- tion of reference materials the determination of minimum sample amounts required to obtain normally distributed results and for the methodology of solid sample analysis.1.5.3. Chemometrics A major aim of chemometrics is to aid the optimization and212R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 interpretation of results in a more time effective way. The use of simplex and its various modifications factorial designs with multivariate response functions signal pro- cessing and pattern recognition methods all fall under this general heading. Although the area has been reviewed (91/C737) each of these areas has been the subject of a number of publications. Simplex methods are widely used to maximize the S/B ratio of selected peaks although the choice of response function step size and starting condi- tions and the difficulties encountered with factors that have different significance may sometimes limit the utility of the technique.A set of programs have been presented which enable the simplex optimization of a process that involves ten interdependent variable factors (9 1/945). The programs written in Applesoft BASIC are fully listed. They are based on the modified simplex method and are suitable for use in optimizing any instrument process or situation that involves 2- 10 variables. Evolving factor analysis has been applied to FI analysis data (9 1 / 1 162). The concentra- tion profiles and spectra of Bi3+ and the bismuth chloride complexes BiC12+ through BiC13-were estimated from injection of bismuth perchlorate into a flowing stream of 1.0 mol 1-l HC1.The estimated spectra compared favour- ably with previously published spectra of the complexes. An exploratory study on medium-based robust regression methods for linear calibration in AAS analysis has been conducted (90/1984). A strategy was developed either to avoid the influence of outliers or to reject them in the case of homoscedasticity in routine analysis. Several robust methods based on the median i.e. the single median the repeated median and the least median of squares were introduced and evaluated. The methods were used for the analysis of real data obtained from AAS studies. The application of different multivariate and discriminant analyses and factor analyses have been used to characterize polluted soils by AAS (91/23 1) while principal components analysis correspondence factor analysis and spectra map analysis have been applied to spectroscopic data (90/29 15).In both instances the information obtained by displaying the objects and variables in each reduced factor space was compared and the redundant information shown. An objective evaluation of precision requirements for geoche- mical analysis using analysis of variance has also been discussed (90lC4065). The partial least squares method(PLS) and its application in analytical chemistry has been the subject of a review of 58 references (9013459). Baxter and Oehman (90/3974) have presented the possibility of mathematically resolving spectral interferences using multicomponent standard addi- tions and PLS modelling. The method was applied to the determination of Au in the presence of cobalt at the 242.8 nm wavelength with continuum source background correc- tion (90/3974) and As in the presence of aluminium and phosphates (9 VC749).More accurate results were ob- tained by the application of this procedure than by conventional single-component standard additions methods. However it should be noted that the successful application of this procedure requires knowledge of the sample constituent causing the spectral interference and that its concentration can be increased by standard addi- tions. The possibility of resolving spectral interferences in ETAAS by applying multivariate calibration has been investigated (9013974). Resolution is achieved using multi- component standard additions (the so-called generalized standard additions method or GSAM) combined with PLS modelling.The multivariate calibration method PLS-GSAM was described and its use illustrated by application to the determination of Au by ETAAS in the presence of cobalt at the 242.8 nm wavelength where severe spectral interference problems are observed using continuum source background correction. The inherently multiparameter character of atomic spectra has also been used to illustrate the utility of multilinear or regression- based calibration techniques (90lC2922). A critical assess- ment was made of the use of the 1024 pixels available on a conventional linear photodiode array when used with a spectrally segmented photodiode array spectrometer. Prin- cipal component analysis has been reported for a number of applications including a classification of polluted and unpolluted mussels using data obtained by ETAAS (90/1180) and in data analysis of heavy metal pollution in the sea (1911354).A mathematical treatment based on the analysis of the atomization pulse and its derivatives has been reported for the description of the atomization in a graphite furnace (90/1985). By observing that the absorbance rate presents a maximum and a minimum at times t and t, respectively and that for all the experimental situations studied the temperature had reached a plateau before tpt. the rate equations were solved using boundary conditions at t rather than at the beginning of the pulse. Simple and physically valid equations were obtained for the determina- tion of the rate constants (k and kJ for the formation and loss of atoms.Monte Carlo algorithms and the computa- tional power of a supercomputer have been combined with spatially resolved atomization profiles obtained by using a spatial isolation wheel (9 l/C1983). This combination of experiment and theory has led to an insight into the energetics of processes occurring in the graphite tube which are not available directly from conventional techniques such as Arrhenius plots. Finally the nature of the signal from a graphite furnace has been investigated using computer simulations of atomization and diffusive removal (90/3966). 2. ATOMIC FLUORESCENCE SPECTROMETRY In previous reviews atomic fluorescence spectrometry (AFS) has been presented under several headings princi- pally as inductively coupled plasma and laser-excited AFS (LAFS) (ASU-Atomization and Excitation J.Anal. At. Spectrom. 1990 5 189R and 205R). These continue to be the most active research areas though in terms of practical applications cold vapour methods for Hg gener- ation of hydrides (or other volatile compounds of the analyte element) and gas chromatographic systems com- bined with conventional light sources appear to be the most widely used. Sophisticated light sources such as the ICP or laser do not readily transfer into the routine analytical laboratory. Atomic fluorescence spectrometry is at its most useful when conventional light sources are used and when there is either very little sample matrix or the analyte element can be separated from it. As atomic fluorescence is used along with molecular fluorescence as a diagnostic aid in studies of combustion and of the plasma this use of fluorescence will also be presented in this review.As an aid to the practical application of AFS a table of data on 76 elements collected from 322 references has been compiled by Winefordner’s Group at the University of Florida (9011 186). The table includes the excitation and fluorescence wavelengths atom reservoir excitation source limit of detection and comments on the types of samples analysed. A review of Chinese publications on AFS has been prepared by Yingqi (9013470).JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 213R 2.1. Discharge Lamp Excited Atomic Fluorescence The light sources used in practical AFS are generally EDLs or pulsed HCLs.An exception was the use by D'Silva and Zamgow (901C3230) of a helium afterglow discharge detec- tor (HeAD) into which H2S and PH3 were introduced in order to produce intense emission of S and P. This radiation was used to excite the fluorescence of S and P as they were atomized by a second HeAD through which the effluent of a GC system was passed. By this means the effect of the intense emission of CO in the HeAD was reduced. When a xenon$ashtube was used to irradiate Cd atoms in an ICP (90/3300) approximately 87% of the fluorescence signal observed at 643.8 nm was related to double resonance fluorescence. This phenomenon is a disadvantage in analytical applications owing to its large potential for interferences. Ionic absorbance orfluorescence are rarely used analytically however a technique for generating intense ion emission has been described (9 11C2 146).When a commercial Ca HCL was driven with a 1.5 ps 28 A current pulse the intensity of the Ca I1 393.3 nm line was enhanced by a factor of more than 1 x lo6. Many of the papers to be reviewed here rely upon cold vapour procedures or gas chromatography for vaporizing the analyte prior to atomization in a flame or plasma. By these means the analyte element is separated from its matrix and the background signal that the latter may generate is thereby eliminated. Acceptable S / N ratios can thus be achieved with less intense excitation sources than for example a laser. This approach was followed by Rigin (911247 9 11848). A comprehensive scheme for the genera- tion of volatile compounds of analyte elements was devel- oped.The method was based on the autoclave decomposi- tion of a bulk sample using xenon tetrafluoride with subsequent conversion of the analyte elements into volatile compounds that were then isolated as a gaseous analytical concentrate. Atomization of the gas phase was by an air- cooled ICP. It was found that interferences were eliminated and the system could be calibrated with pure compounds of the element without the need for matrix matching. As the analyte was determined free of its matrix this method was proposed as a possible approach to absolute analysis by AFS. Non-dispersive systems with EDL excitation HG and atomization in an Ar-H,-entrained air flame are a feature of the AFS determination of As Bi Hg Sb and Se.Such systems have been applied after appropriate sample pre- treatment to the analysis of geological material (90/3469) food products (911446) and copper (91158). A dual channel system has been described by Guo et al. (901 1832). Spectral interference in the determination of Bi was overcome by using a bromide EDL in place of the usual iodide lamp. The detection limits for As Bi Hg and Sb in geological samples were 0.1 0.001 0.002 and 3.0 ppm respectively. The performance of a flame-based system was improved by passing the liberated hydrides through an electrically heated quartz tube furnace operating at 900 "C prior to entering the flame. These systems have been used in the analysis of geochemical samples (9 1 /4 1 1 9 1/432) and coal fly ash fish liver and muscle and sea-water (9014 152).Electrodeless discharge lamps may be constructed to operate at either microwave- or radio-frequencies. The latter mode gave improved performance in the determination of Sn in tungsten steel and molybdenum steel by HG non-dispersive AFS (9013524). The detection limit was 3.4 x g of Sn. Instrumentation specifically constructed for the determi- nation of Hg in air and water by cold vapour AFS has been described by Stockwell et al. (90lC2985). The instrument has a wide linear dynamic range and high sensitivity. In an FI system (90140 19) organo-mercurials were photo-decom- posed by passing the aqueous sample through a quartz tube and irradiating it with a 400 W UV lamp. Inorganic Hg was reduced to elemental Hg by tin@) chloride and the Hg released was extracted into Ar through a porous PTFE membrane.Fluorescence at 253.7 nm was excited by a low pressure Hg lamp and measured with a solar blind PMT. The detection limit was 0.18 ppb of Hg from 600 pl of sample. Organo-mercurials have also been decomposed using bromine monochloride following the elimination of interfer- ing organic substances with acidic potassium permanganate (911C2145). Detection limits by cold vapour AFS of eight different organic and inorganic forms of Hg were 2.3 x pg ml-l and recoveries were between 94 and 105%. A pulsed Hg HCL was used in conjunction with cold vapour generation and atomization in an MIP (911C2147). A detection limit of 3 ppb of Hg was achieved under optimized operating conditions.Two conference papers (9 1 1C20 1 6 9 1 /C2092) have recommended that AF should be considered as an alternative to AA for the measurement of Hg using standard and EPA methods of sample prepara- tion and Hg liberation. As the feasibility of determining Hg by AF has been long established the fact that it has not evolved into a standard method poses an intriguing question. The ICP as an atomizer in AFS has the advantage over the flame of being able to atomize refractory materials. Nebulization eficiency is an important factor in determin- ing the sensitivity of both techniques when analysing solutions. The use of an ultrasonic nebulizer in conjunction with an ICP resulted in superior detection limits in the sub- ppb range (911C486). The addition of alcohol to aqueous solutions is another well-known technique for producing a greater proportion of smaller droplets when the solution is nebulized. This approach has been applied to the determi- nation of Eu in yttrium oxide (9 11C2122).The tendency to form refractory oxides in the tail plume of the ICP was also reduced and a detection limit of 24 ng ml-l of Eu was obtained. A commercial ICP-AFS system (Baird AFS 2000) has been evaluated for the multi-element analysis of impurities in uranium (901C1890) and the determination of precious metals in geological samples (9 11725). Detection limits for Au Pd and Pt were 1 0.5 and 12 ng ml-l respectively. Calibration graphs were linear over 5 orders of magnitude. Analyses of CRMs were satisfactory and long- term reproducibility was f 5Oh.A pulsed HCL ( 5 kHz 300 mA) AFS system was developed by Klunder and Boss (901C1607) for use with a uniform-size droplet generator in order to study ligand interferences on Co signals in fuel-rich flames. The vapour cloud produced by individual droplets was observed. Changes in the rates of the desolvation and vaporization processes for different complexes were determined with a view to relating them to changes in free atom formation. 2.2. Laserexcited Atomic Fluorescence Spectrometry General reviews of LAFS have been published by Fujiwara (9 11140) and Omenetto (9112678). Winefordner et al. have carried out a theoretical study of single atom detection by LAFS or LEI (901C1583 9012207). They concluded that from practical considerations none of the conventional analytical approaches can achieve single-atom detection with the possible exception of an ionization method coupled with atomization in vacuum.Arising from the absence of reference materials with certified metal contents in the 0.1 pg g-l or 1 fg ml-l region the practicality of absolute analysis by LAFS has been examined by Omenetto (91x1743). The feasibility of using photodissociation lasers in LAFS has been investigated by Simeonsson et al. (901C1587 9 1/2445). Such lasers produce coherent line radiation214R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991 VOL. 6 which is inherently tuned to atomic transitions and thus overcomes the problems of linewidth and de-tuning that arise with tunable dye lasers. Experiences in the measure- ment of T1 and In were reported and compared with other atomic spectrometric methods. In an analytical system as complex as LAFS it is inevitable that processes other than the one generating the analytical signal should occur and thereby modify the response.The presence of unvaporized droplets in the analytical volume irradiated by the laser could modify the analytical response by absorbing laser energy their explo- sive evaporation (91/2223) or focusing the laser beam to cause dielectric breakdown and the generation of a plasma (9 1 /2 2 2 5). 2.2.1. Electrothermal atomization In a conference paper (90/C2099) Michel et al. reported that for elements of medium to high volatility detection limits with ET-LAFS were in the 0.1-100 fg range. These values were 1-4 orders of magnitude more sensitive than those for ETAAS in the same furnace.Petrucci et al. (90/C1621) using flame and furnace atomization have also reported detection limits in the femtogram range. In addition they undertook an initial evaluation of ionization detection of the LAFS signal generated in several atomiza- tion sources; the outcome should be of considerable interest. The technique which has been termed resonance detection is predicted to have a spectral selectivity of the order of 10 pm. Furnace atomization systems usually operate on discrete samples however Womach et al. (91/293) have developed a system for continuous sample introduction into a ceramic atomization furnace. The system was optimized for the determination of Pb and achieved a detection limit of 2 ng ml-* with a linear calibration graph over three orders of magnitude.A much lower detection limit 0.05 pg ml-l was obtained with discrete sample atomization and a frequency-doubled dye laser pumped by a high repetition rate Cu vapour laser (90/1954). By means of a capacitor discharge heated anisotropic graphite furnace a heating rate of 60 000 "C s-l was achieved in the determination of T1 in NIST biological samples (91/C1991). An integration time of 80 ms gave a detection limit of 5 fg of T1. The performance of three lasers nitrogen copper vapour and Nd:YAG as pumps for tunable dye lasers used in the determination of Fe Ga In Ir Pb and T1 by ETAFS has been studied by Vera et al. (90/2236). Detection limits for Ir ranged from 0.5 fg with the copper vapour laser to 10 pg with the nitrogen laser for Ga they were 2 pg with the copper vapour laser and 25 fg with the Nd:YAG laser and for Pb the detection limit was the same 3 fg for both nitrogen and Nd:YAG lasers.The same group of workers (90/1986) carried out a study of the ET-LAFS determina- tion of Ga In and yb by double resonance excitation and achieved detection limits of 1 2 and 220 fg respectively. However single-resonance excitation direct line fluores- cence remained the preferred scheme for less volatile elements with strong direct line fluorescence such as Fe Pb and T1. When a laser was used in place of a discharge lamp for excitation of In atomized from a tungsten spiral atomizer (90/1936) the detection limit was lowered by two orders of magnitude to 1 x g.Even under optimal conditions of synchronized laser and atomizer pulsing there was considerable attenuation of the fluorescence signal. The background and the S/N ratio of an AFS system are closely linked hence when narrow bandpass filters (1 nm) were used to exclude background radiation in a non- dispersive instrument the noise was reduced and detection limits improved to 1 fg (90/4155). The S / N ratio was also improved when the signal level was increased by raising the pulse rate of the exciting radiation from 100 to 500 Hz (90/C1586 90/C2996); a reduction in the detection limit of T1 from 3 to 1 fg was achieved. Methods have been developed for the correction of background e.g. Zeeman effect (90/C2996 9 1/C1993) or the simultaneous measure- ment of scattered and black-body radiation at wavelengths adjacent to that of the fluorescent radiation (90/4156 9 ~ 2 6 2 2 ) .In an examination of the analysis of real samples by ET-LAFS Michel et al. (90/C2099) found that the only significant background signals they detected were black- body emission from the furnace and stray light caused by the scatter of laser radiation off surfaces of the instrument. Scatter by matrix species could be removed by proper charring of the sample prior to atomization. While calibration graphs in ET-LAFS are linear over 4-6 orders of magnitude non-linearity may appear at high concentrations of analyte. The on-set of non-linearity was believed by Dougherty et al. (91/1534) to be caused primarily by post-filter effects. For non-resonance LAFS long lifetimes for the terminating energy levels in the fluorescence processes were postulated to increase the probability of post-filter effects.Conditions that increased the residence time of atoms in the furnace (gas stop and platform atomization) produced the same effect. Successful practical applications of ET-LAFS have in- cluded the determination of Hg in air at the pg m-3 level (9 1/ 163) and Co Fe Ni and Pb in high-purity Si02 at the 1 x 10-4-1 x level (91/339). Michel et al. (91/C734) analysed a variety of SRMs in order to ascertain the magnitude of background signals and the accuracy and precision of the determination of Mn Pb and T1. Results were comparable with those obtained using ETAAS. The same paper reported great sensitivity in the determination of F in water and urine by laser-excited molecular fluores- cence of the magnesium fluoride molecule vaporized in the graphite furnace.Lead and T1 were successfully determined in nickel-based alloys by direct solid sampling graphite furnace LAFS (90/C1676 91/1426 911C1938). Ultimate detection limits in the range 1 x 10-4-1 x lo-' pg g-l using a 1 mg sample were predicted. The RSDs were 7-14% with an accuracy in the measurement of nickel-based alloy SRMs of = 10%. 2.2.2. Low pressure atomization systems For the determination of isotopes by LAFS it is necessary that the exciting laser has a narrow linewidth and the sample is atomized at low pressure. Niemax (90/3403) using a sample mounted in a vacuum chamber compared four techniques for this purpose excitation in an atomic beam orthogonal to the laser beam saturation spectros- copy off-resonance multi-photon spectroscopy and reso- nant multi-photon spectroscopy.The first technique gave especially efficient excitation. In other studies employing closed systems the same group used laser (Nd:YAG) ablation as a means for atomizing metallic samples for LAFS analysis (9 1 /95 9 1/C6 18). With reliable lasers and time-gated detection systems fluorescence intensities could be measured with small standard deviations but were strongly dependent on the pressure of the noble gas buffer. The dynamic range covered four orders of magnitude and detection limits were of the order of 0.3 pg for B Cr Mg Mn and Si in low-alloy steels copper and aluminium. Using this system these workers demonstrated (9 1/22 12) that internal standardization can be applied successfully to the determination of elements by LAFS of microplasmas produced by laser ablation of solid samples.The ratios of the signals from ground-state atoms of Cr Mg Mn and Si when probed by laser-induced fluorescence (LIF) were found to a first approximation to be independent of theJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY7 AUGUST 199 1 VOL. 6 215R matrix the amount of ablated material and plasma temper- ature. These ratios therefore could be used as a basis for internal standardization. Russian workers have been active in investigating the merits of atomization in low-pressure environments. Bo1'- shov et al. claimed (91/271) that for some sample types vacuum ETA aflords almost 100% eficiency without matrix eflects.The technique incorporating a graphite vessel with quartz windows for atomization at 10 mTorr and 3000 "C and a Nd:YAG laser for excitation was used to determine Co in high-purity tin vegetables and quartz and also Ru in geological samples. A commercially available cathodic sputtering cell designed for AAS was adapted for LAF measurements (90lC1624). An improvement in detection limits of 1-2 orders of magnitude over AAS was achieved. By normalizing the LAF signal from Fe to the AES signal from Cu reasonable linearity across a series of SRM brasses of widely varying composition was achieved. Sputtering was also used in a study of the direct analysis of high-purity materials by LAFS (91/1598). In the determination of Pb in pure copper and Si in pure germanium detection limits were 2-3 ng g-l.The study also investigated the possibili- ties of a planar magnetron as an atomizer and LAFS detection as a means for the determination of both surface and volume contamination of solids. There was reasonable agreement between theoretical and experimental calibra- tion graphs. The sensitivity of the determination of Co by hot hollow cathode AES (91/338) was improved by 3-4 orders of magnitude when the discharge process was used to atomize dry solution residues and an LAF signal was generated by a Nd pumped dye laser. Smith et al. (90/1189) employed a commercially available HCL as the atom reservoir and excitation by a copper laser pumped dye laser for the determination of Pb by LAFS. By virtue of the very low background emission and excellent atomization charac- teristics of the glow discharge a detection limit of 1.8 ag was achieved.A pulsed glow discharge was used as an atomizer for LAFS by Click et al. (90/3343 911C1999) and Khvostikov and Grazhulene (90/C3 142). By firing the laser 0.1 ms after the end of the discharge pulse the fluorescence signal was generated when the atom population was still large but the background emission had become negligible. Pulse repetition rates of the order of 10 Hz were employed. Detection limits for Ir and Pb were 20 and 0.5 pg respectively. Gas analysis by LAFS is relatively undeveloped owing in part to the fact that the resonance transitions of most gases lie in the VUV region for which intense lasers are not available.Bol'shakov et al. (9 1/873) have circumvented this problem by populating metastable states of the analyte species in a plasma at a gas pressure of 4 kPa and then exciting fluorescence from that state with a laser. The detection limit for Ne in helium was 0.3 ppb Ne in argon < 100 ppm and N2 in helium and argon 1 ppb after oxidation to NO2. 2.3. Inductively Coupled Plasma Excited Atomic Fluores- cence The ICP as an emission source in AFS is a means of achieving an intense multi-element source for a wide range of elements. Greenfield and co-workers have continued their pioneering work (see Anal. Proc. 1984 21 61) exploring the possibilities of dual plasma (atomizer-source) systems. They have confirmed (91/C823) using the dual plasma system that a reduction of spectral interferences can be achieved by replacing AES detection with AFS.A small effect due to increased background noise was noted for a few elements when high concentrations of interferents were nebulized into the atomizer plasma. Improvement in the optical and sample transfer efficiency of the original instrument led to a 3-fold decrease in the detection limit (90/C3221). The system was applied to the determination of refractory elements (Mo V W and Zr) following preconcentration on Amberlite IRA-93 (90/1467 90/1748 9013503). The purpose of the work was to develop a preconcentration procedure for the simultaneous determina- tion of a number of refractory elements. The method was suitable only for Mo and W and achieved detection limits of 15 and 65 ng ml-1 with a precision of 5.2 and 4.3% respectively.From a comparison of a boosted discharge HCL with an ICP employed as excitation sources for AF in the tail flame of an ICP the same workers (90/3969) concluded that when the lamps were over-run there was no difference in the radiance of the sources. The lamps gave rise to lower blank standard deviation values but poorer sensitivity owing to inefficient irradiation of the analytical volume in the plasma. An air ICP has been investigated by Seltzer and Green (90K1585) as an atom source for ICP- LAFS. It was suggested that the higher ground state atom population and superior thermal properties of the air ICP could lead to lower detection limits. The background continuum was lower than that of the Ar ICP but there was considerably more band structure in the air ICP.2.4. Studies of Flames and Plasmas Using Laser-induced Fluorescence The fluorescent lifetime of the Na 589.18 nm line in atmospheric pressure CH4-0,-diluent (N2 or Ar) flames was measured by Alfono (90/2272) using a high repetition rate (3.8 MHz) picosecond dye laser with gated photon counting detection. The lifetime was found to change from 0.61 to 0.80 ns over a 3 mm region above the flame (CH4-02-N2) reaction zone. At the same location in the flame the lifetimes were 1.10 ns with Ar as the diluent and 0.56 ns when N2 was used. A hollow cathode atom/ion beam source was used to make accurate measurements of absolute transition probabilities by means of LAFS and FTS (90/C159 1). Time resolved LAF measurements of radiative lifetimes in the range 2 ns-2 ps were accurate to within 5%.The intrinsic advantage of FTS over scanning spectropho- tometry of simultaneous measurement on all spectral elements facilitated the measurement of branching ratios in complex atomic spectra throughout the spectral range from the UV to IR. Absolute transition probabilities were derived from lifetime and branching ratio data. Two-photon LIF has been used to detect oxygen atoms in the gas phase above a heated catalytically stabilized combuster (9 1/7 13); excitation was at 226 nm and detection at 777 nm. Strong interfering background signals were reduced by spatial and spectral filtering. The detection limit for oxygen was estimated to be 5 x 1 OI3 atoms cm-'. Atomic oxygen has also been detected using the four-wave mixing technique of third harmonic generation (9 112224).Third harmonic generation provides state selective low aperture detection with sensitivity comparable to other optical methods. Ground-state oxygen was generated using a microwave discharge and detected by focusing a 391 nm dye laser beam into the post-discharge region with measure- ment at 130 nm. The detection limit was 5 x l O I 3 atoms (approximately 2 ppm at atmospheric pressure). Measurement of OH in flat stoichiometric CH,-air flames burning at 1 2 5 7 and 9.6 bar have been carried out by LIF and resonance coherent anti-Stokes Raman scattering (CARS) (9014 179). Temperature and OH concentrations were derived from the data. Neither method was superior to the other; e.g. resonance CARS might be chosen because of its coherent nature or LIF because of its two dimensional imaging capabilities.Dunn-Rankin et al. (9 1 /2225) have examined sources of possible error in gas temperature measurements made by CARS in the presence of liquid216R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 droplets. The droplets can cause dielectric breakdown of a plasma by focusing the CARS laser beam. These effects reduce the peak signal intensity and raise the background intensity. Correction procedures were devised whereby the systematic error was reduced to within one standard deviation of the drop-free measurements of temperature. Rensburger et al. (90/1973) examined in depth the systematic errors in the determination of temperatures in low-pressure flames by LIF arising from spectral bias time delay temporal sampling rate optical depth and rotational level dependence of the fluorescence quantum yield for each radical (OH NH CH and CN).The severity of these problems is different from each radical and must be evaluated experimentally. The discrepancies between esti- mates of temperature made with and without correction for the systematic errors could be as much as several hundred degrees. Laser atomic fluorescence in conjunction with atomic emission was used to probe the spatial dependence of atom and ion density in an Ar ICP as a function of aerosol transport rate (90/4 1 54). Fluorescence responsivities (sig- naYmass of analyte) either remained constant or in- creased as sample aerosol transport rate increased while ion emission responsivity decreased.The changes in AE and AF responsivities with aerosol loading were spatially dependent. Laser-induced fluorescence of Ba and Sr was used to study the three-dimensional spatial distribution of atoms in a three electrode d.c. plasma (90/C1817 90/3492). It was found that the distribution of barium ion ground states was determined primarily by flow dynamics round the Ar plasma jet. The portion of the plasma where emission was generated was small com- pared with the over-all spatial distribution of the analyte indicating that only a small fraction of the total analyte present contributes to the emission signal. The presence of Na and other easily ionized elements did not alter the spatial distribution of Ba but did cause ionization suppression.3. LASER-ENHANCED IONIZATION Laser-enhanced ionization (LEI) uses laser radiation to excite atoms to levels from which ionization by thermal processes is increased significantly i. e. the current flowing between electrodes placed in the atom vapour increases when the vapour is laser irradiated. Direct laser ionization (laser photoionization) i.e. situations where all the ioniza- tion energy is supplied optically will also be considered. This latter technique is most commonly used in association with low-pressure systems such as resonance ionization mass spectrometry (RIMS) (see Atomic Spectrometry Update-Inorganic Mass Spectrometry and X-ray Fluores- cence J. Anal. At. Spectrum. 1990 5 250R). There is a low but sustained level of interest in LEI and associated techniques.The processes occurring during LEI are com- plex and will doubtless be a fruitful field for study for some time to come. The widespread exploitation of LEI as a universal analytical method however does not appear likely in the foreseeable future despite its potential for high sensitivity. This review is based on approximately 20 published papers and ten conference presentations. Previous reviews can be found in Atomic Spectrometry Update-Instrumen- tation J. Anal. At. Spectrum. 1990 5 152R and Atomic Spectrometry Update-Atomization and Excitation J. Anal. At. Spectrum. 1990 5 180R. A thorough general review of atomic ionization spectrometry has been published by Kuzyakov and Zorov (91/1134). The principles fea- tures advantages and applications of the technique are presented.Laser-enhanced ionization in flames has been reviewed by Axner and Rubinsztein-Dunlop (90/ 1849 90/3953 9 1/99) and high-resolution laser-induced ioniza- tion spectroscopy by Bushaw (90/332 1). Conference review papers have been presented by Winefordner (9 1/C568) Rubinsztein-Dunlop (9 1/C62 1) and Green and Seltzer (91/C2021). 3.1. Systems Operating at Atmospheric Pressure Practical applications of LEI in flames have been described by Turk and Kingston (90/C1765). The NIST (Washington DC USA) programme for the certification of SRMs has employed LEI based methods for several years. It was found (9 ~ 1 4 2 5 ) that interference from alkali and alkaline earth elements present in biological samples necessitated the removal of those elements by chelation chromatography.In two papers (9 ~ 2 4 2 6 9 1/2427) Axner and co-workers reported investigations of the interference effect of sodium. To reduce the effect a two-laser system was used one to ionize sodium while the other probed a volume 4 mm higher in the flame for the analyte where the population of sodium atoms was depleted. This approach reduced the sodium signal by up to 5-fold. An alternative approach to improve discrimination against sodium was careful selec- tion of laser power. The optimum power is determined by factors that are specific to each experimental set-up. This latter approach was derived from a fundamental theoreti- cal and experimental study of one-step LEI transitions for atoms in flames (9112213).A simplified expression for the one-step LEI signal strength as a function of excitation wavelength was derived. From this expression general element-independent predictions of the most sensitive unsaturated one-step LEI transitions were made for 13 elements. Other workers (9 1 /C2 144) have examined the interference of radicals e.g. OH CH and C2 in an air-C2H2 flame on the LEI detection of trace elements in the UV spectral region. They found for example that a strong OH band causes serious deterioration in the detec- tion of Pb at 283.3 nm and advised that fundamental studies of laser ionization of radicals are an important aspect of LEI determination of elements with high ioniza- tion potentials. For the determination of Cs in cadmium mercury telluride by single and double-step excitation schemes (90/3048) nebulization of the sample solution into an air-C4H,,,-C3Hs flame was compared with evaporation from a heated pyrolytic graphite rod into the flame.For both techniques the detection limits and linear dynamic ranges were 0.1 pg and 1 pg ml-’-10 pg ml-l respectively; accuracy and precision were good for the determination of 1 x 10-9-1 x lO-’Oh Cs. The lower limit of the linear range of a flame-based LEI method for the determination of Mg was reduced by two orders of magnitude to 1 ng 1-l when the conventional two-electrode system was replaced by a three-electrode arrangement (90/ 1 523). This configuration facilitated differential signal measurement whereby the level of electrical interference from the pulse voltage generator of the nitrogen pumping laser was reduced.Using a pre-mixed air-C,H2 flame Turk and Travis (91/2204) investigated random signal fluctuations of simultaneously detected LEI and LIF. They found a greater degree of noise correlation between the two techniques than between either technique and laser power fluctuations. They proposed a scheme for background correction in LEI by utilizing the LIF signal of the interferents and the noise correlation between LEI and LIF. Axner and Sjostrom have examined spectral broadeningJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 217R of the LEI signal from Sr (460.733 nm) in a flame (91/C623 9 1/723) when optical saturation conditions prevail (laser power 11 kW cm-2). They observed a narrow peak on top of a broader peak.The latter was attributed to the theoretically predicted effect whereby the width of the measured peak increases as the square root of the light intensity. It was proposed that the narrow peak arose from ionization of atoms outside the primary (laser beam defined) interaction region by radiation scattered from the laser beam. This effect is particularly significant when beams of small diameter and high intensities are used and can lead to errors when number densities ionization yields signal enhancement and saturation effects are studied by LEI. It has been proposed (9 1/C 1994) that the spatial distribution of ionization may be studied by observing the LEI signal as a function of the voltage between the detection electrodes. As the voltage applied to the cathode increases the effective electric field extends further from the cathode into the flame; the burner being at ground potential.Progressively more of the flame and its ion content is sampled as the voltage increases. Graphite probe furnace LEI has been proposed (90/C1620 90/C303 1) as a means of minimizing gas-phase reactions between the analyte and its matrix. Biological reference materials were used to evaluate the potential of the system for the analysis of real samples. Michel et al. (901C2099) followed a similar approach but additionally used the probe as an electrode and thus avoided sample re- condensation on the electrode. Plasmas provide alternative but difficult to exploit atomizers for LEI. In the past the tail flame of an ICP has been used for this purpose (e.g.91/2460) rather than the AE analytical zone. Some recent work (90/C1623) however has been directed at utilizing the latter. By momentarily switching off (1.5 ms) the r.f. power (1 kW) in synchronism with firing of the laser an ionization signal could be detected with water-cooled copper electrodes. The electrical conductivity properties of an MIP have been examined with a view to its use as a source for LEI (90/1485). Argon and Ar-active N2 plasmas were investigated. In the latter plasma suppression of the signal by thermally ionized Group 1A elements was encountered. 3.2. Systems Operating at Reduced Pressure The potential and limitations of isotope ratio measure- ments using ETA into a low pressure noble gas atmosphere and resonant Doppler-free two-photon LEI spectroscopy have been examined (90141 12).It was concluded that the technique could be an alternative analytical technique to mass spectrometry provided physical effects such as laser instablity and gas-temperature fluctuations which can give rise to systematic errors are eliminated. The precision of the absolute measurement of isotopes was 10-1 5% but for isotope ratios it was 2-5%. A special vacuum chamber with a rapid sample turn around time and incorporating a graphite tube furnace was constructed by Stevenson et al. (901C1622) in order to facilitate studies designed to characterize and optimize resonance ionization spectroscopy (RIS) as an analytical method. The factors affecting the atomization eflciency of a vacuum furnace system for atomic ionization spectrometry have been studied by Russian workers (9011223).They found that the molecular collision number in a tube atomizer was a quadratic function of the ratio of the tube length to its internal diameter and concluded that vacuum atomization requires a stricter approach to establishing the accuracy of the analysis than conventional methods involv- ing atomization in gaseous media. Laser-enhanced ionization was used to generate ions in a laser microprobe system in which the vaporization wave- length was tuned in resonance with the analyte (Cu or Na) absorption band (90/C 1638). A 70-fold enhancement of the ion intensity from the resonant transition was observed. The acoustic wave generated by the laser plume in the He atmosphere was used to monitor the total amount of material vaporized during each laser pulse.Laser ablation of sodium tungstate in vacuo was used in the study of laser power effects on LEI measurements of the Na D-line (9 1 /722 9 K2033). Laser-enhanced ionization spectral broadening occurred as the power of either the ablating or exciting laser was increased. Ion intensity showed a linear response to changes in laser power. At 1 atm of He severe collisional broadening was observed. High resolution and low sensitivity occurred with low excitation intensity; the reverse was true at high intensity. 4. ATOMIC MAGNETO-OPTICAL ROTATION SPECTROMETRY Atomic magneto-optical rotation spectrometry (AMORS) also known as coherent forward scattering (CFS) uses the rotation of the plane of linearly polarized resonance radiation by a magnetized atomic vapour to generate an analytical signal.The birefringent and dichroic properties of the vapour are a consequence of the Zeeman effect in the atom. The analytical signal may be recorded either as a change in the intensity of radiation transmitted by a system of crossed polarizers or as the angular rotation of the plane of polarization of the incident radiation. The latter may be observed directly (91lC462; see also Monnig C. A. Madison R. T. and Hieftje G. M. Appl. Spectrosc. 1990 44 216) or computed from measurements of transmitted intensity (91/796). A review of developments in AMORS was presented in Atomic Spectrometry Update-Atomiza- tion and Excitation J. Anal. At. Spectrom. 1990 5 210R. Research activity in AMORS is currently at a low level and is undertaken in probably no more than ten laboratories worldwide.As far as can be judged at the present time AMORS will remain a laboratory novelty until some as yet unrecognized outstanding advantage of the technique over established techniques is revealed. Some advantages of AMORS over other spectroscopic techniques particularly with respect to background correction have been reviewed by Stephens in a conference presentation (9 VC689). To date the lowest detection limits obtained by AMORS have been comparable to those obtained by AAS using the same instrumental system (e.g. 9 1/462). A detection limit for Ag of 1 ppb was reported for a Voigt (transverse magnetic field) configuration system employing ETA (90/C2043).Errors resulting from background absorption and fluctuations in the intensity of the HCL were reduced by the use of a rotating polarizer with a stationary analyser. The ratio of the energies transmitted when the planes of the two polarizers were parallel and orthogonal was calculated to give a corrected signal (see also Dawson J. B. Duffield R. J. Kersey A. D. Hajizadeh-Saffar M. and Fisher G. W. J. Anal. At. Spectrom. 1987 2 233). Zhao et al. (91/2447) using a pulsed HCL examined the influence of light source S/N ratio continuum background and struc- tured interference on the determination of Au in rocks and minerals. A detection limit of 14 pg and satisfactory precision and accuracy were achieved. Simultaneous multi- element analysis by AMORS using a crossed polarizer configuration with a continuum light source (xenon arc) has been reported by Hermann et al.(9 1 / 199). In this arrange- ment the AMORS process becomes in effect a high- resolution spectrometer which transmits radiation from the source only at resonance wavelengths. Its effectiveness is limited by the extinction coefficient of the crossed polariz-218R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1 99 1 VOL. 6 ers emission from the graphite furnace and the quadratic nature of the response curve. The instrument which was a development of one previously reported (9.011 172) was applied to the determination of Ca Cd and Mg. used light sources only weakly emit such lines. Extended working ranges were achieved by the use of very weak absorption lines for the measurement of high concen- trations.This approach to the determination of major constituents is not feasible in AAS because the commonly LOCATION OF REFERENCES The full list of references cited in this Update have been published as follows 90/1159-90/C1460 J. Anal. At. Spectrom. 1990 5(4) 167R-178R. 90/1461-90/2277 J. Anal. At. Spectrom. 1990 5(6) 2 15R-242R. 90/2278-901359 1 J. Anal. At. Spectrom. 1990 5( 7) 278R-32 1 R. 9013591-90/4179 J. Anal. At. 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ISSN:0267-9477
DOI:10.1039/JA991060187R
出版商:RSC
年代:1991
数据来源: RSC
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Atomic spectrometry update references |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 221-227
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JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 221R ATOMIC SPECTROMETRY UPDATE REFERENCES The address given in a reference is that of the first named author and is not necessarily the same for any co-author. 9112703. 9112704. 9112705. 91 12706. 9 112707. 9112708. 9 112709. 9 1/27 10. 911271 1. 9112712. 91/27 13. 9 1/27 14. 9 1/27 1 5. Kuroda R. Wada T. Soma T. Itsubo N. Oguma K. Determination of trace concentrations of indium in silicate rocks by graphite furnace atomic absorption spectrometry Analyst 1990 115 1535. (Lab. Anal. Chem. Fac. Eng. Univ. Chiba Yayoi-cho Chiba Japan). Karadjova I. Arpadjan S. Mandjukov P. Deligeorgiev T. Solvent extraction of cadmium cobalt copper iron man- ganese nickel and zinc into isobutyl methyl ketone with 2- (2-benzoxazolyl)malonaldehyde and 24 2-benzoxazolyl)cya- noacetaldehyde.Extraction-atomic absorption spectrome- tric determination of trace amounts of the metals in molybdates Analyst 1990 115 1539. (Fac. Chem. Univ. 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Determination of sodium in a new additive for unleaded gasoline by flame AAS (Vqskumny ostav pre Ropu a Uhl’ovodikovt Plyvy ViEie Hrdlo 824 17 Bratis- lava Czechoslovakia). 91/C2743. Helsin V. Hetko Z. Loskotovsi I. Analyses of ?tee1 wires on optical emission spectrometers (Tiineckt Zelezdrny s.P. 739 70 Tiinec Czechoslovakia. 9 1x2744. Hlavhtek I. Hlavhtkovai I. Determination of boron in boron-alloyed steels by inductively coupled plasma atomic emission spectrometry (Chem.Lab. Poldi United Steelworks Pnimyslovd ul. 272 62 Kladno Czecho- slovakia). /C2745. HlaviitkovA I. HlavBtek I. Utilization of inductively coupled plasma atomic emission spectrometry (ICP-AES) to analysis of titanium alloys and their master alloys (Chem. Lab. Poldi-SONP United Steelworks Pnimyslova ul. 272 62 Kladno Czechoslovakia). /C2746. Holhyovai G. Mathemy M. Matrix effects in the deter- mination of Cd by the ETAAS method (Dept. Hyg. Epid. Fac. Med. Univ. P. J. SafArik KoSice Czechoslovakia). /C2747. k i c k y V. Toman J. ICP-OES determination of rare earth elements (REE) in their ores and concentrates (UNIGEO State Estab. Lab. Cent. Brno Polni 23/25 Czechoslovakia). /C2748. Kirsch M. Application of ICP spectrometry for routine analyses of metal alloys (Dept.Metall. Inst. Res. Dev. Povaiskt Strojdme Povaiskd Bystrica Czechoslovakia). /C2749. LUiment V. Inter-element correction for boron determina- tion in Fe and Co alloys by ICP-AES (Inst. Phys. SAS Dubravckd casta 9 Bratislava Czechoslovakia). 9 1 ~ 2 7 5 0 . Koller L. Excitation temperature radial distribution in the d.c. arc device by MarinkoviC (Dept. Chem. Tech. Univ. KoSice Czechoslovakia). 91K2751. Kopecky J. Bernas M. Homan J. Tiirk P. Proko- povsi H. Spectral plate evaluation by means of a semi- conductor image sensor (CCD) (CVUT Elektrotech. Fak. Prague Czechoslovakia). 911C2752. KoSiIi M. Korpei t. Feriantik E. Some problems in the determination of rhenium by ICP-AES in geological samples (Geol. Priesk. h i t . Podnik Spiiskd Nova Ves Czechoslovakia).91K2753. Kotrly S. Approaches to the margins of analytical informa- tion limit of detection and limit of determination (Dept. Anal. Chem. Univ. Chem. Technol. 532 10 Pardubice Czechoslovakia). 91/C2754. Krakovskri E. Utilization of a Weta 82 tungsten atomizer for the determination of rare earth elements (Dept. Chem. Tech. Univ. KoSice Czechoslovakia). 91/C2155. Kriirik P. Msisilko R. Mcha S. Determination of some noble metals in waste waters using the Philips PV 8065 emission spectrometer (Lab. At. Spectrom. Inst. Chem. Technol. Prague Czechoslovakia). 9 1/C2756. Martiny E. Medv& J. Rojkovi6 I. Problems of rare earth elements determination in the Permian silicate rocks from the Western Carpathians by atomic spectroscopic methods (Geol.Inst. Slovak Acad. Sci. Bratislava Czechoslovakia). /C2757. Mathemy M. Origination and development of atomic spectrochemistry in Slovakia (Fac. Metall. Tech. Univ. KoSice Czechslovakia). K2758. Musil J. Direct analysis of the ‘difficult’ biological samples by means of ICP-AES (Inst. Landscape Ecol. CSAV Ceskt Budiijovice Czechoslovakia). /C2759. Nevoral V. Determination of traces of vanadium in mineral waters (Inst. Balneolog. Res. Czechoslovakia). 91K2760. Paukert T. RubeSka I. Weiss D. Determination of REE by ICP optical emission spectrometry after organic solvent extraction (Geol. Surv. Prague MaIostranske n. 19 1 182 1 Prague 1 Czechoslovakia). 9 1x276 1. PlieBovsksl N. hltt!s P. Correlation study of internal standardization in inductively coupled plasma atomic emission spectrometry (Fac.Metall. Tech. Univ. KoSice Czechoslovakia). 9 1/C2762. Polakovitovh J. Kubovd J. Some problems of determina- tion of Ta Nb Hf and Zr in geological samples by ICP- OES (Geol. Inst. Fac. Natl. Sci. Komensky Univ. Mlynskd Dolina 842 1 5 Bratislava Czechoslovakia). 9 1/C2763. ReitznerovA E. Determination of trace elements As Bi Pb Sb and Sn in high quality copper by AAS method (Res. Lab. Metal Mater. Tech. Univ. KoSice Czechoslovakia). 91K2764. RiSovh J. Hladkf Z. FiSera M. Determination of some essential and trace elements in brain by ICP-OES and AAS methods (Fac. Chem. Technol. Slovak Tech. Univ. Dept. Anal. Chern. Radlinskeho 9 812 37 Bratislava Czecho- slovakia). 91/C2765. Rubeska I. Paukert T. Determination of platinum group elements using fire-assaying with collection into NiS but- tons (Geol.Surv. Prague Malostranske n. 19 1 182 1 Prague 1 Czechoslovakia). 91K2766. Rybkovi g. Situation in the research of rare earth elements according to the bibliographic data in the period 198 1-1 988 (Fac. Metall. Tech. Univ. KoSice Czecho- slovakia). 9 1/C2767. Sokolovh B. Direct determination of trace metals in hydrocracker feed by the ICP-AFS method (Lab. Element. Anal. Dept. Quality Control Slovnaft Bratislava Czecho- slovakia). 911C2768. StreSko V Veber M. GomiSPek S. Determination of trace elements in waters by AAS after on-line preconcentra- tion (Geol. Inst. Fac. Nat. Sci. Komensky Univ. 84215 Bratislava Mlynskd Dolina Czechoslovakia). 9 l/C2769. Zdenek S. Determination of chromium in biological materials by methods of atomic spectroscopy-present situation problems and perspectives (Fac.Agron. Univ. Agric. CS-165 2 1 Prague 6-Suchdol Czechoslovakia). 9 l/C2770. Splhacek R. Method development for determination of lead zinc cadmium and copper in milk and dairy products with graphite furnace atomic absorption spectrometry (Vyskumny Ustav Potravinarsky Bratislava Czecho- slovakia).JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 223R 9 l/C277 1. Toman J. ICP-OES in organic solvents (UNIGEO State Establishment Lab. Cent. Brno Polni 23/25 Czecho- slovakia). 9 1x2772. Vida S. F16rih K. Solairikovd M. Testing of the spectral line pairs for the analytical calibration of LMA steels (Res. Testing Inst. East-Slovak. Metall. Works KoSice Czecho- slovakia).91/C2773. Vinklerovd s. Luzar O. Spectroflame-ICP and its utiliza- tion in the laboratory (Res. Inst. NHKG Ostrava Czecho- slovakia). 9 1x2774. bmberyovd M. Vatkovd M. Smirnovd L. Electrothermal atomization of metal chelates for analytical application (Dept. Anal. Chem. Fac. Sci. Komenskjr Univ. 842 15 Bratislava Czechoslovakia). 9 112 775. 91/2776. Jerrow M. Marr I. Cresser M. S. Magnesium as a modifier for the determination of barium in offshore oil- well waters by direct current plasma atomic emission spectrometry and flame atomic absorption spectrometry Analyst 1991 116 141. (Dept. Chem. Univ. Aberdeen Meston Walk Old Aberdeen AB9 2UE UK). Volynsky A. Tikhomirov S. Elagin A. Proposed mecha- nism for the action of palladium and nickel modifiers in electrothermal atomic absorption spectrometry Analyst 1991 116 145.(V.I. Vernadsky Inst. Geochem. Anal. Chem. USSR Academy of Sciences 19 Kosygin St. 1 17975 Moscow USSR). Papers 9 112775-9 1lC2898 were presented at the 199 1 European Winter Conference on Plasma Spectrochemistry Dortmund Germany 14th- 18th January 199 1. 91/C2777. 91/C2778. 91/C2779. 9 1/C2780. 91/C278 1. 91lC2782. 91lC2783. 91lC2784. 9 1 lC278 5. 9 l/C2786. 9 1 lC278 7. 91lC2788. humans P. W. J. M. Signal-to-noise and signal-to- background from confusion to fusion! (Philips Res. Labs. P.O. Box 80.000 5600 JA Eindhoven The Netherlands). Hieftje G. M. Plasma diagnostic techniques for under- standing and control (Indiana Univ. Dept. Chem. Bloom- ington IN 47405 USA). Bol’shov M. A.Applications of laser-induced fluorescence in spectrochemistry (Inst. Spectrosc. USSR Acad. Sci. 142092 Troitzk Moscow USSR). Nickel H. Characterization of metallic and ceramic high- temperature materials for energy systems by means of atomic spectroscopy (Forschungszent. Julich GmbH Inst. fur Reaktorwerkstoffe Lehrstuhl Reaktorwerkstoffe Bren- nelemente RWTH Aachen Postfach 19 1 3 5 170 Jiilich Germany). Oechsner H. SNMS-a plasma based method for solids mass spectrometry (Dept. Phys. Inst. Surf. Thin Film Anal. Univ. Kaiserslautern D-6750 Kaiserslautern Germany). Horlick G. Plasma mass spectrometry for elemental analysis (Dept. Chem. Univ. Alberta Edmonton Alberta T6G 2G2 Canada). Mermet J.-M. Sampling of metals for inductively coupled plasma spectrochemistry (Lab.Sci. Anal. Univ. Lyon I 69622 Villeurbanne Cedex France). Sam-Medel A. Role of plasma spectrochemistry in clinical and biological analysis a challenge called speciation (Dept. Phys. Anal. Chem. Fac. Chem. Univ. Oviedo Spain). Pliko E. Evaluation of different approaches to correction of background and/or spectral interferences (Geol. Inst. Comenius Univ. Mlynskfi Dolina 842 15 Bratislava Czechoslovakia). Berndt H. Schaldach G. Hydraulic high pressure nebuli- zation a new aerosol generation and an on-line sample pretreatment system (Inst. Spektrochem. angew. Spek- trosc. Bunsen Kirchhoff Str. 11 D-4600 Dortmund Ger- many). Dittrich K. Nagora B. Niebergall K. Matrix interference in ETV-ICP-AES (Univ. Leipzig Sect. Chem. Anal. Cent. Leipzig 0 70 10 Germany). Satyanarayana H.Sikoo B. M. Determination of rare earth elements (REE) yttrium and scandium in geological materials and rare earth concentrates using inductively coupled plasma emission spectrometry (Chem. Lab. At. 91/C2789. 9 1lC2790. 91K2791. 91x2792. 91lC2793. 9 1lC7294. 91K2795. 91lC2796. 9 1x2797. 9 1 K279 8. 91x2799. 9 1 /C2800. 91lC2801. 91fC2802. 91lC2803. 9 1/C2804. 91lC2805. Min. Div. Dept. At. Energy Begumpet Hyderabad 5000 16 India). Zairav Gv. -tor T. Derecskei B. Direct analysis of aluminium oxide using an ETVD-ICP method with gaseous halogenization (Eotvos Univ. Budapest Hungary Tech. Univ. Budapest Hungary). Cassagne P. Johnson T. J. Routh M. W. Selection of analytical lines for use in inductively coupled plasma atomic emission spectrometry-a novel approach to the way out of the nightmare (ARL Appl.Res. Lab. En Vallaire CH- 1024 Ecublens Switzerland). Steffan I. Vujicic G. Influence of alcohols on plasma discharge performances (Inst. Anal. Chem. Univ. Vienna A-1090 Vienna Waenringerstr. 38 Austria). Montaser A. Clifford R. H. Sohal P. Dual-beam light- scattering interferometry for simultaneous measurements of droplet-size and velocity distributions of aerosols produced by new ultrasonic nebulizers (Dept. Chem. George Wash- ington Univ. Washington DC 20052 USA). van Voen F. H. de Loos-Vollebregt M. T. C. Power of Kalman filtering for data reduction in ICP-AES (Lab. Anal. Chem. Delft Univ. Technol. de Vries van Heystplantsoen 2 2638-RZ Delft The Netherlands). Yang J.-f. Zeng X.-j. Matrix interferences from elements with different ionization potentials in inductively coupled plasma atomic emission spectrometry (Changchun Inst.Appl. Chem. Acad. Sin. Changchun 130022 China). Moenke-Blankenburg L. Giinther D. Schumann T Quantification in LM-ICP-AES (Martin-Luther-Univ. Halle-Wittenberg Dept. Chem. Weinbergweg 16 0-4050 Halle/S Germany). Sansoni B. Panday V. K. Present state of instrumental multi-element analysis by ICP atomic fluorescence spectro- metry with hollow cathode lamp excitation (Dept. Chem. Anal. Res. Cent. Julich GmbH D-5170 Julich-1 Ger- many). Vertes A Baiazs L. Gijbels R. Crater and plume formation in laser-solid interaction (Univ. Antwerp Dept. Chem. Univ. l. B-2610 Wilrijk Belgium). Steers E. B. M. Leis F. Excitation processes in a Grimm-type glow discharge lamp with and without supple- mentary microwave excitation (DECAP Polytech North London Holloway London N7 6DB UK).Winchester M. R. Marcus R. K. Emission characteristics of a pulsed r.f. glow discharge atomic emission source (Dept. Chem. Howard L. Hunter Chem. Labs. Clemson Univ. Clemson SC 29634- 1905 USA). Ronan G. Clark J. Wheeler D. The use of magnetically confined electron beam enhanced glow discharge for the direct bulk analysis of insulating and conducting samples (VG MicroTrace Ion Path Rd. Three Winsford Cheshire CW7 3BX UK). Sommer D. Grunenberg D. Koch K. H. SNMS and GD- OES for steel surface analysis a comparative study (Hoesch Stahl AG Postfach 10 50 42 D-4600 Dortmund Ger- many). Hunault P. Le Marchand A Brenner I. S. Recent developments in GD-ES instrumentation and methodology for bulk and surface analysis (Jobin Yvon (ISA) 16-18 Rue du Canal Longjumeau Cedex 91 163 France).Xhoffer C. Van Borm W. Van Grieken R. Jacob W. Broekaert J. Study of exhaust aerosols in slurry nebuliza- tion inductively coupled plasma atomic spectrometry for ceramic powders (Dept. Chem. Univ. Antwerp (ULA) Universiteitsplein 1 B-26 10 Antwerp-Wilrijk Belgium). Kuss H.-M. Mueller M. Bossmann D. Trace element determination in steel samples by means of ICP-MS (Univ. Duisburg Dept. Anal. Chem. Duisburg Germany). Jakubowski N. Feldmann I. Stuewer D. Berndt H. Schaldach G. Hydraulic high pressure nebulization-ap- plication of a new nebulization system for ICP-MS (Inst. Spektrochem. Angew. Spektrosk. Postfach 10 13 52 D- 4600 Dortmund 1 Germany).224R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1 99 1 VOL.6 91/C2806. Okamoto Y. Shimam S. High sensitivity microwave- induced plasma mass spectrometry for trace element analy- sis (Cent. Res. Lab. Hitachi Kokubunji Tokyo 185 Japan). 9 1/C2807. Vzlllkopf U. Analysis of solid microsamples using ETV- ICP-MS (Bodenseewerk Perkin-Elmer GmbH D-7770 herlingen Postfach 10 1 1 64 Germany). 91/C2808. Sullivan J. J. Quimby B. D. Bandemer T. Stable isotopes in gas chromatography using an atomic emission detector (Hewlett-Packard P. 0. Box 900 Avondale PA 1931 1 USA). 9 1 /C2809. Shuttleworth S. Spatially resolved elemental analysis of ceramic materials by LA-ICP-MS (VG Elemental Ion Path Rd. Three Winsford Cheshire CW7 3BX UK). 91/C28 10. Horlick G.Stewart M. Automated solution sample preparation for inductively coupled plasma spectrometry (Dept. Chem. Univ. Alberta Edmonton Alberta T6G 2G2 Canada). 91/C28 11. Brill M. Heraeus W. C. Cassagne P. High precision measurements in the precious metals industry with induc- tively coupled plasma atomic emission spectrometry (Her- aeusstrasse 12-1 4 D-6450 Hanau 1 Germany). 9 K 2 8 12. Wok Ad. Uitbeijerse E. Inorganic multi-element analysis using inductively coupled plasma atomic emission spectro- metry according to the contract laboratory program (CLP) quality control regulations (Baird Europe B.V. Produk- tieweg 30 2382 PC Zoeterwoude The Netherlands). 91K2813. LobirIski R. Broekaert J. A. C. Tschgpel P. Inductively coupled plasma atomic emission spectroscopic determina- tion of trace impurities in Zr02 powder (Max-Planck Inst.Metallforsch. Lab. Reinststoffanal. D-4600 Dortmund 1 Germany). 9 1x28 14. Revesz R. Hasty E. Microwave sample preparation utilizing temperature feedback control (CEM P.O. Box 200 Matthews NC 28 106 USA). 91/C2815. Brenner I. B. Le Marchand A. Optimization of intensity measurement and acquisition in multi-element sequential analysis by ICP-AES-variable resolution and mathemati- cal modes of measurement drastically improves S/B ratios (Jobin Yvon (ISA) 16-18 Rue du Canal Longiumeau Cedex 9 1 163 France. 91/C2816. Brenner I. B. Gautherin J. C. Le Marchand A. Lavenir E. Samuel O. Lagave X. Rapid analysis of complex materials by ICP-AES-application of elemental tracers for rapid analysis of high solid and viscous materials (Jobin Yvon (ISA) 16-18 Rue du Canal Longiumeau Cedex 9 1 163 France).91/C2817. Campbell M. Vandecasteele C. Dams R. Application of isotope dilution techniques to the accurate and precise determination of lead in reference materials by inductively coupled plasma source mass spectrometry (Lab. Anal. Chem. Univ. Gent Inst. Nuc. Sci. Proef- tuinst. 86 B-9000 Gent Belgium). 91/C2818. C a d M. Mermet J.-M. Considerations of the practical determination of limits of detection in inductively coupled plasma atomic emission spectrometry (Lab. Sci. Anal. Univ. Lyon I 69622 Villeurbanne Cedex France). 91K2819. Dixon A. Gregson D. Hutton R. C. Potter D. Normali- zation of mass response function in ICP-MS (VG Elemen- tal Ion Path Rd. Three Winsford Cheshire CW7 3BX UK).9K2820. Ediger R. D. Fredeen K. J. Automatic interpretation of ICP-MS spectra using heuristic-based methods (Perkin- Elmer 761 Main Ave. Norwalk CT 08659-0219 USA). 91X2821. Eid M. A. Fakhry A. A. Eid K. A. Broekaert J. A. C. Selection of analysis lines for spectrometric determination of REE in phosphates (Phys. Dept. Natl. Res. Cent. Dokki Cairo Egypt). 91IC2822. Fecher P. ICP emission with an ultrasonic nebulizer-a routine tool for analysing food samples? (Landesuntersu- chungsamt Gesundeit. Nordbayern Henkestrasse 9- 1 1 8520 Erlangen Germany). 91/C2823. Fredeen K. J. Denoyer E. R. Hager J. W. Laser sampling ICP-MS methods development strategies (Perkin-Elmer 761 Main Ave. Norwalk CT 06859-0219 USA). 91/C2824. Horlick G. Qin F. Characterization of high frequency signal fluctuations in inductively coupled plasma atomic emission spectrometry (Dept.Chem. Univ. Alberta Ed- monton Alberta T6G 2G2 Canada). 91/C2825. Chomet S. Trassy C. Imbert J. L. Study of alkaline interference at low concentration in ICP by optical spectros- copy and mass spectroscopy (Sew. Cent. D’anal. CNRS-BP 22-6930 Vernaison France). 91/C2826. Ivaldi J. C. Slavin W. Analytical testing procedures for inductively coupled plasma atomic emission spectrometry (Perkin-Elmer 76 1 Main Ave. Norwalk CT 06859-0237 USA). 91/C2827. Montaser A. Tan H. Ishii I. Nam H. Analytical and fundamental characteristics of the Delsi-Nermag mass spectrometer interfaced to a versatile ICP system (Dept. Chem. George Washington Univ. Washington DC 20052 USA).91/C2828. Niilte J. Applications of a flow injection device for sequential ICP instruments (Bodenseewerk Perkin-Elmer GmbH Postfach 10 11 64 D-7770 ijberlingen Germany). 91IC2829. Routh M. W. Cassagne P. Johnson T. J. Influence of sample introduction temperature stabilization in ICP-AES (ARL Applied Research Laboratories En Vallaire CH- 1024 Ecublens Switzerland). 91K2830. Samuel O. Gautherin J. C. Le Marchand A. Wallerand C. -re E. Polyscan ICP spectrometers-scanning poly- chromators for problem solving in multi-element analysis (Jobin Yvon (ISA) 16-18 Rue du Canal Longjumeau Cedex 9 1 163 France). 91/C2831. Goudzwaard M. P. de Loos-Vollebregt M. T. C. Charac- terization of noise in inductively coupled plasma atomic emission spectrometry (Delft Univ. Technol. Lab.Anal. Chem. De Vries van Heystplantsoen 2,2628 RZ Delft The Netherlands). /C2832. Verrept P. Vandecasteele C. Dams R. Electrothermal vaporization for sample introduction in ICP-AES with automatic background correction (Lab. Anal. Chem. Inst. Nucl. Sienc. Univ. Ghent Proefruinstraat 86 B-9000 Gent Belgium). /C2833. Rudolph O. Wundrack A. Low-noise high sensiti- vity-atomic emission spectroscopy with TEP-excitation source (Gesellschaft Anal. Atomspektrosk. Me0 technik mbH Am Bahnnof 413315 Bad Durrenberg 0-4203 Ger- many). /C2834. Walsh A. Analysis of difficult matrices by high resolution ICP-MS (VG Elemental Ion Path Rd. Three Winsford Cheshire CW7 3BX UK). K2835. Yang J.-f. Piao Z.-x. Zeng X.-j Studies on derivative techniques in inductively coupled plasma atomic emission spectrometry (Changchun Inst.Appl. Chem. Acad. Sin. Changchun 130022 China). 91/C2836. Yates D. A. Fredeen K. J. Salit M. L. Collins J. B. Automated background Correction techniques in ICP spec- troscopy (Perkin-Elmer 76 1 Main Ave. Norwalk CT 91/C2837. Denoyer E. R. Fredeen J. Application of laser sampling ICP-mass spectrometry to environmental analysis (Perkin- Elmer 761 Main Ave. Norwalk CT 06859-0219 USA). 9 1/C2838. Gercken B. Barnes R. M. Combination of size exclusion chromatography and ICP-MS for blood speciation analysis of lead and other trace elements (Dept. Chem. Univ. Massachusetts GRC Towers Amherst MA 01003 USA). 9 1 /C2839. Scholze H. Stephanowitz H. Hoffmann B. Determina- tion of B Al Si Zn Mo and W in concentrated alcalic solutions with an ICP spectrometer Spectro- flame (Inst.Chem. Technol. Rudower Chaussee 5 0- 1 199 Berlin Germany). 91K2840. Tang Y.-o. Du Y. Zhu M.-h. Shao J.-c. Liu C. Air-argon ICP for organic solution analysis spectro- 06859-02 19 USA).JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 225R scopic characters and analytical proformance (East China Inst. Chem. Technol. Anal. Res. Center Shanghai 200237 China). 9 1/C284 1. Feldmann I. Jakubowski N. Stuewer D. Improvement of pneumatic nebulization in ICP-MS by desolvation (Inst. Spektrochem. Angew. Spectroskop. Postfach 10 13 52 D- 4600 Dortmund 1 Germany). 911C2842. BelQzs L. Vertes A. Gijbels R. Absorption and emission mechanisms in laser generated plumes (Univ. Antwerp Dept. Chem. Universiteitsplein 1 B-26 10 Wilrijk Bel- gium).9 1x2843. Bol’shakov A. A. Golovenkov N. V. Laser-induced fluores- cence analysis of inorganic species in the gaseous phase (Inst. Phys. Leningrad State Univ. Petrodvorets Lenin- grad 198904 USSR). 9 VC2844. Bol’shakov A. A. Golovenkov N. V. Stepwise plasma-laser fluorescence detection of gas impurities (Inst. Phys. Lenin- grad State Univ. Petrodvorets Leningrad 198904 USSR). 91lC2845. Broekaert J. A. C. Brushwyler K. R. Bricker T. Hieftje G. M. Investigations at a jet-assisted glow discharge lamp for optical emission spectrometry (Indiana Univ. Dept. Chem. Bloomington IN 47405 USA). 91/C2846. Clark J. Ronan G. Greb U. Wheeler D. The effects of cryo-cooling and plasma cell geometry on the performance of GDMS (VG Microtrace Ion Path Rd.Three Winsford Cheshire CW7 3BX UK). 9K2847. Eberhardt K. Buchert G. Hermann G. Trautmann N. Microwave-induced plasma operated at atmospheric and low pressure as an ion source for a mass separator (Inst. Kernchemie Univ. Mainz Fritz-StraBmann-Weg 2 D- 6500 Mainz Germany). 91K2848. Fujimori H. Matsui T. Izumi S. Hsueh Y. M. Detection of fine particles in liquids by a laser breakdown method (Energy Res. Lab. Hitachi 1 168 Moriyama Hitachi Ibarak 3 16 Japan). /C2849. HergenrMer R. Niemax K. Continuous wave field ioniza- tion laser spectroscopy (Inst. Spektrochem. angew. Spec- trosk. (ISAS) D-4600 Dortmund 1 Germany). /C2850. Hunault P. Chewier M. Passetemps R. Application of GD-ES (glow discharge emission spectrometry) for the direct analysis of non-conducting materials and coatings (16-18 Rue du Canal Longjumeau Cedex 91 163 France)./C285 1. Jenett H. Effects of instrumental parameters on quantifica- tion and depth resolution in secondary neutral mass spectrometry (Inst. Spektrochem. angew. Spektrosk. Post- fach 101352 D-4600 Dortmund 1 Germany). 91lC2852. BNS~ J. Uebbing J. Sdorra W. Leis F. Niemax K. OES measurements at laser-produced plasmas re-heated by a second pulse laser (Inst. Spektrochem. Angew. Spektros- kop. Bunsen-Kirchhoff-Str. 1 1 D-4600 Dortmund 1 Ger- many). 91/C2853. Lunvov 0. S. Maximov D. E. Oshemkov S. V. Rud- nevsky A. N. Determination of metal traces by laser- excited fluorescence method with hot hollow cathode atomization (Inst. Phys. Leningrad Univ. Leningrad USSR). 91K2854. Lazik C. Marcus R. K.Influence of anode geometry in radiofrequency glow discharge emission spectrometry (Dept. Chem. Howard L. Hunter Chem. Labs. Clemson Univ. Clemson SC 29634-1905 USA). 91/C2855. Cable P. R. Marcus R. K. Ion sampling considerations for an r.f. glow discharge source with external sample mount geometry (Dept. Chem. Howard L. Hunter Chemical Labs. Clemson Univ. Clemson SC 29634-1905 USA). 91/C2856. Milton D. Raith A. Ronan G. Analysis of metals and alloys using quadrupole-based glow discharge mass spectro- metry (VG MicroTrace Ion Path Rd. Three Winsford Cheshire CW7 3BX UK). 91K2857. Funtov V. N. Nemets V. M. Petrov A. A. Soloviov A. A. Peculiarities of the isotope composition spectroscopic de- tection in a gas discharge plasma (Inst. Phys Leningrad Univ. Leningrad 198904 USSR).9K2858. van Straaten M. Vertes A. Gijbels R. Modelling of atomization processes in a glow discharge ionization cell (Univ. Antwerp Dept. Chem. Universiteitsplein 1 B-26 10 Wilrijk Belgium). 911C2859. Ronan G. Milton D. Wheeler D. Raith A. Quantitative depth profile analysis using the VG GloQuad (VG Micro- Trace Ion Path Rd. Three Winsford Cheshire CW7 3BX UK). 91/C2860. Vieth W. Huneke J. C. Influence of source configuration and discharge conditions on GDMS analytical perform- ance (Charles Evans & Associates 301 Chesapeake Dr. Redwood City CA 94063 USA). 911C2861. Del Monte Tamba M. G. Tomellini R. Lo Piccolo E. Study of the kinetics of sputtering of pure metals and alloys under glow discharge conditions (Cent. Sviluppo Mater. Via Caste1 Romano 100-102 00129 Rome Italy).91/C2862. Miller K.-H. Beckmann B. Oechsner H. Analysis of insulating materials by the high frequency mode of secon- dary neutral mass spectrometry (Dept. Phys. Inst. Surf. Thin Film Anal. Univ. Kaiserslautern D-6750 Kaiserslau- tern Germany). 911C2863. Hoffmann E. Liidke Ch. Skole J. Simultaneous multi- element determination of toxic elements in airborne dust by FANES (Cent. Inst. Opt. Spectrosc. Berlin Germany). 91/C2864. Kisnimote T. Wenzel N. GroBe-Wilde F. Liipke G. Marowsky G. Investigation of C02 laser plasmas by coherent anti-Stokes Raman scattering (CARS) (Siemens AG Forschungslab. D-8520 Erlangen Germany). 91/C2865. Pangav V. K. Dadmun J. T. Sansoni B. Instrumental multi-element analysis by ICP atomic fluorescence using hollow cathode lamps influence of mineral acid and salt concentration (Cent.Lab. Chem. Anal. Res. Cent. Julich Postfach 19 13 D-5 1 70 Julich Germany). 9 1/C2866. Gunther D. Kammel J. Moenke-Blankenburg L. LM- ICP-AES-tandem technique for direct solid analysis of conducting and non-conducting materials (Martin-Luther- Univ. Halle-Wittenberg Dept. Chem. Weinbergweg 16,O- 4050 Halle Germany). 91/C2867. Wennrich R. Niebergall K. Nguyen H. Th. Dittrich K FANES and ICP-AES with laser ablation REE analysis in solid samples (Univ. Leipzig Sekt. Chem. WB Analytik Talstr. 35 0-70 10 Germany). 91K2868. Hoffmann V. Jaknbowski N. Stahlberg U. Stuewer D. Investigations comparing the analysis of massive and compacted metallic materials by glow discharge mass spectrometry (GDMS) (Inst.Spektrochem. Angew. Spek- troskop. Postfach 10 13 52 W-4600 Dortmund 1 Ger- many). 9 1 /C2869. Gries W. Siipitz W. Tilch J. Laser-excited atomic fluorescence spectrometry-application to the determina- tion of palladium (Laser Anal. Res. Tempelhofer Ufer 23-24 W- 1000 Berlin 6 1 Germany). 9 1 /C2870. Bauer G. Wegscheider W. Ortner H. M. Estimation of errors and limits of detection in ICP-OES using univariate and multivariate calibration (Inst. Anal. Chem. Micro- Radiochem. Graz Univ. Technol. Technikerstrasse 4 A- 80 10 Graz Austria). 9 1 /C287 1. Bliidorn W. Burba P. Jiiger H. Trace element determina- tion in contaminated soil solutions and landfill leachates by atomic spectrometry a comparison of different preconcentration procedures (Spectro Anal. In- strum. Kleve Germany).91/C2872. Miema J. Ramsza A. P. Investigation of some analytical parameters and spectral characteristics of MIP spectrome- try with wet aerosol introduction (Cent. Lab. M.C.S. Univ. 20-03 1 Lublin Poland). 91/C2873. Senron H. ICrieg M. Wienke D. Improvement of the detection limits for the trace element determination in A1203 by thermochemical reactions and nonlinear blank correction (Friedman-Schiller Univ. Jena Inst. Anorgan. Anal. Chem. D-0-6900 Jena Germany). 9 1IC2874. Jonkers Ch. Janssens K. Van Espen P. Simultaneous multi-element analysis of steel using glow discharge mass226R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991 VOL. 6 spectrometry (Cent. Micro- Trace Anal. Dept. Chem. Univ. Antwerp Universiteitsplein 1 B-26 10 Wilrijk Bel- gium).9 1/C2875. Niitzold C. Z. Quillfeldt W. ICP-instrument approach with fibre optics PLASMAQUANT 100 (Jenoptik Carl Zeiss JENA GmbH Geschaftsbereich Opt. Anal. 0-6900 Jena Germany). 911C2876. Niebergall F. Wennrich R. Multi-element trace analysis in penicillin G by ICP-AES (Univ. Leipzig Sekt. Chem. WB Anal. Talstr. 35 Leipzig 0 7010 Germany). 911C2877. Chaplygina N. I. Popandopulo Yu. I. Grazhulene S. S. Elimination of the matrix element influence in ICP-OES analysis of high purity Zn and Cd (Inst. Microelectron. Technol. Problems USSR Acad. Sci. 142432 Chernogo- lovka USSR). 911C2878. Caroli S. Violante N. Quaglia M. G. Lopez A. Trace elements as potential markers for identifying the geographi- cal origin of addictive drugs (1st. Super. Sanita Dept.Appl. Toxicol. Viale Regina Elena 299 00161 Rome Italy). 1C2879. Caroli S. Coni E. Fornarelli L. Falconieri P. Assessment of reference values for trace elements in human milk (1st. Super. Sanita Dept. Appl. Toxicol. Viale Regina Elena 299 0016 Rome Italy). 1C2880. Shabani M. B. Masuda A. A study of on-line preconcen- tration of ultra-trace levels of rare earth elements in complex matrices and sea-water using phosphate base complex immobilized on XAD-4 amberlite by means of ICP-MS (Dept. Chem. Fac. Sci. Univ. Tokyo Hongo 113 Tokyo Japan). 911C288 1. Nickel H. Zadgorska Z. Optimization of electrothermal vaporization of impurity elements in Sic powder using inductively coupled plasma atomic emission spectrometry (Inst. Reactor Mater. Res. Cent. Julich P.O. Box 1913 5 170 Julich Germany). 911C2882.Xu L.q. Schramel P. Determination of gold in sludge and soil by sequential ICP after preconcentration and separation with thiol-cotton fibre (Inst. okologische Chem. GSF D- 8042 Neuherberg Germany). 9 11C2883. Wiinsch G. Seubert A. HPLC trace-matrix separation procedures for Mo and W and their use with ICP-OES (Univ. Hannover Inst. Inorg. Chem. Callinstr 9 D-3000 Hannover 1 Germany). 9 1/C2884. Wisbrun R. Niessner R. Laser induced breakdown spec- troscopy for detection of heavy metals in environmental samples (Inst. Water Chem. Tech. Univ. Munich Mar- chioninistr. 17 D-8000 Munchen 70 Germany). 91/C2885. van Veen E. H. Tiggelman J. J. Wassink A. P. Kalter A. Determination of trace elements in uranium by ICP-AES using Kalman filtering (Lab.Anal. Chem. Delft Univ. Technol. de Vries van Heystplantsoen 2 2628 RZ Delft The Netherlands). 9 1K2886. Steffan I. Vujicic G. ICP-AES analysis of non-conductive powders after spark ablation (Inst. Anal. Chem. Univ. Vienna A- 1090 Vienna Waenringerstr. 38 Austria). 9 1 /C2887. Schramel P. Xu L.q. Knapp G. Application of an on-line preconcentration system in simultaneous ICP-AES (Inst. Okologische Chem. GSF D-8042 Neuherberg Germany). 911C2888. Sanz-Medel A. Shchez Uria E. Menendez A. Cotrino J. Quintero M. C. On-line chemical pretreatments for direct and indirect analysis of iodide by plasma atomic emission spectrometry (Dept. Phys. Anal. Chem. Univ. Oviedo Spain). 911C2889. Richts U. Broekaert J. A. C. Tschiipel P. Tiilg G. Comparative study of a Beenakker cavity and a surfatron in combination with electrothermal evaporation from a tung- sten coil for microwave plasma optical emission spectrome- try (Inst.Spektrochem. Angew. Spektrosk. (ISAS) Postfach 10 13 52 D-4600 Dortmund 1 Germany). 9 11C2890. Vereda Alonso E. Garcia de Torres A. Sanchez Rojas F. Can0 Pavh J. M. Determination of nickel by ICP spectrometry involving a prior extraction with 1,5-bis(di-2- pyridyl methylene) thiocarbonohydrazide into methyl iso- butyl ketone and butyl alcohol. A comparative study (Dept. Anal. Chem. Fac. Sci. Univ. Miilaga 29071 Miilaga Spain). 911C2891. Leiterer M. Ettig St. Griin M. Determination of heavy metals in soils and sewage sludges by inductively coupled plasma atomic emission spectrometry-investigations on matrix effects (Inst.Plant Nutr. Ecotoxicol. Jena Naum- burger Stralje 978 Jena 9 Germany). 911C2892. Lathen C. Docalkal B. Broekaert J. A. C. Tschiipel P. Tiilg G. Determination of trace elements in a silicon carbide powder (Inst. Spektrochem. Angew. Spektrosk. (ISAS) Postfach 10 1 3 52 D-4600 Dortmund 1 Germany). 911C2893. Krause P. Meyberg F. Dannecker W. Application of ICP-OES and ICP-MS to the analysis of airborne pariculate matter determination of trace elements and matrix charac- terization (Univ. Hamburg Inst. Anorg. Angew. Chem. Martin-Luther-King-Platz 6 D-2000 Hamburg 13 Ger- many). 911C2894. Krause P. Hamester M. Dannecker W. Analysis of weathered sandstones using laser ablation inductively coup- led plasma mass spectrometry (Univ. Hamburg Inst. Anorg. Angew.Chem. Martin-Luther-King-Platz 6 D-2000 Hamburg 13 Germany). 9 l/C2895. Uitbeijerse E. Klok A. Simultaneous analysis of hydride forming and non-hydride forming elements with ICP (Baird Europe B.V. Produktieweg 30 2382 PC Zoeter- woude The Netherlands). 911C2896. Wiinsch G. Knobloch S. Luck J. Bliidorn W. Enrich- ment procedure for water analysis to fulfil the EPA detection limits with ICP-AES (Univ. Hannover Inst. Anorgan. Chem. Callinstr. 9 D-3000 Hannover Ger- many). 911C2897. Gross R. Platzer B. Leitmer E. Schalk A. Sinabell H. Zach H. Knapp G. Atomic emission gas chromatographic detection chemical and spectral interferences in the stabil- ized capacitive plasma (SCP) (Graz Tech. Univ. Dept. Anal. Chem. Micro- Radiochem. Technikerstr. 4 A-8010 Graz Austria).911C2898. Funtov V. N. Nemets V. M. Soloviov,A. A. Spectroscopic measurements in gas chromatography (Inst. Phys Lenin- grad Univ. Leningrad 198904 USSR). Papers 9 112899-9 112928 were presented at the Winter Conference on Flow Injection Analysis Scottsdale AZ USA 6th-9th January 199 1. 9 11C2899. Tyson J. F. Flow injection techniques for preconcentration and matrix isolation in atomic spectrometry (Dept. Chem. Univ. Massachusetts Amherst MA 0 1003 USA). 911C2900. McIntosh S. Li Z. Slavin W. Hergenreder R. Determi- nation of hydride forming elements in various matrices using flow injection atomic absorption spectrometry (Per- kin-Elmer Norwalk CT 06859-0219 USA). 9 1/C290 1. Peski E. F. Automated analyser for the determination of mercury in geological materials (Bonder-Clegg North Vancouver B.C.Canada). 911C2902A. Lancaster H. L. RiiiiCka J. Christian G. D. Preconcen- tration techniques in FIA using sorbent extraction with atomic spectroscopy (Univ. Washington Dept. Chem. Seattle WA 98 195 USA). 911C2902B. Denoyer E. R. Hergenreder R. Georgitis S. Vollkopf U. Using flow injection analysis with ICP mass spectrome- try (Perkin-Elmer 761 Main Ave. Norwalk CT 06859- 02 19 USA). 911C2903. del Barrio S. Vergara A. Valle F. J. Application of the ICP-AES technique to the simultaneous multi-element geochemical analysis optimization of instrumental para- meters (Inst. Tecnol. Geominero Spain). 911C2904. Fariiias J. C. Barba M. F. Inter-element effects in inductively coupled plasma spectrometry (Inst. Ceriimica Vidrio Arganda del Rey Madrid 28500 Spain).911C2905. Sainchez Uria E. Menendez A. Sanz A. New achieve- ments in the use of on-line separations with an ICP-AES detector for the determination of non-metallic elements (Dpto. Quim. Fis. Anal. Fac. Quim. Oviedo 33006 Spain).JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 227R 91/C2906. Sad& M. Lao C. Cotrino J. Spectra acquisition and treatment in a surfatron-MIP (Dpto. Fis. Aplic. Cbrdoba 1407 1 Spain). 91/C2907. Mora J. Hemandis V. Canals A. Thermospray nebulizer preliminary studies for the introduction of organic solutions into an ICP (Dpto. Quim. Anal. Alicante 03071 Spain). 91/C2908. Benavides M. T. Saez M. Cotrino J. Fundamental physical properties of a surfatron-MIP (Dpto. Fis. Aplic. C6rdoba 1407 1 Spain).91/C2909. Basadre M. I. Jouineau M. Study and control of interfer- ences in an ICP (organic solvents introduction). (Dpto. Quim. Anal. Fac. Quim. Univ. Santiago de Compostela Spain). 91/C29 10. Sang R. Latest instrumental developments in ICP emission spectrometry (Chemicontrol S. L. Avda. Pedro Diez 25 Madrid 280 19 Spain). 91/C2911. Barrios V. Canals A. Hemandis V. Design of a high efficiency pneumatic nebulizer for ICP-AES (Dpto. Quim Anal. Univ. Alicante Alicante 0307 1 Spain). 91/C2912. Canto J. Menendez A. Sanchez Uria E. Sanz Medel A. The use of on-line separation techniques for the determina- tion of Sb and Zn electrolysis liquids by ICP (Dpto. Quim. Fis. Anal. Fac. Quim. Oviedo 33006 Spain). 9 1/C29 1 3. Camuiia J. F. Mendndez A. Sanchez Uria E. Sanz Medel A.Liquid-liquid on-line extraction for the determination of ultratraces of A1 using an ICP as the detection system (Dpto. Quim. Fis. Anal. Univ. Oviedo Oviedo 33006 Spain). 91/C2914. Salit M. L. Duffy M. L. Yates D. A. Druszkowski E. Bradley A. F. Advanced internal standard techniques in ICP-AES (Perkin-Elmer Hispania La Mas6 2 Mirasierra Madrid Spain). 9K2915. Fariiias J. C. Barba M. F. Preparation of standard solutions to be used in inductively coupled plasma spectro- metry (Inst. Cerimica Vidrio Arganda del Rey Madrid 22500 Spain). 9 1 /C29 16. Martinez-Lebrusant Ch. Ortega P. Barba M. F. Refrac- tory materials characterization by ICP (Inst. Cerimica Vidrio Arganda del Rey Madrid 28500 Spain). 91/C2917. Rodriguez A. Garcia J. I. Sanz Medel A. Indirect determination of fluoride in waters by liquid chromato- graphy with fluorimetric and ICP detection (Dpto.Quim. Fis. Anal. Univ. Oviedo Oviedo 33006 Spain). 91/C2918. Sbchez M. I. Lux& M. P. Garcia N. Fdas M. Chromophoric element control in raw materials used in the production of white clinker by ICP spectrometry (Inst. CC. Eduardo Torroja (CSIC) C/Serrano Galvache dn. Madrid 8033 Spain). 91/C2919. Fariiias J. C. Barba M. F. Analytical study of advanced 9 1 /C292 9 1 /C292 ceramic materials with Ti-Zr matrix by ICP spectrometry (Inst. Cerdmica Vidrio Arganda del Rey Madrid 28500 Spain). . Quintero M. C. Saez M. Cotrino J. MendzdeG A. Sainchez Uria J. E Sanz Medel A. Determination of iodine and iodides by AES in a microwave plasma (surfa- tron-MIP) (Dpto. Fis. Aplic.Fac. Cienc. Cdrdoba Spain). . Cenera M. L. Navarro A. G6meg J. Montoro R. Determination of As in tinned mussels with dry mineraliza- tion with ICP-AES detection (Inst. Agroquim. Technol. Aliment. Jaime Roig 1 I Valencia 46010 Spain). 91/C2922. Vddes-Hevia C. Fernbdez M. L. Blanco E. Diaz M. E. Sam Medel A. Direct analysis of Co and Cr in commercial glass introducing the sample in the solid phase as a slurry into an ICP (Dpto. Quim Fis. Anal. Univ. Oviedo Oviedo 33006 Spain). 9 1 /C2923. Viillkupf U. Sancho A. Determination of hydride-forming elements by flow injection analysis with ICP-MS detection (Bodenseewerk Perkin-Elmer GmbH Postfach 101 164 D- 7770 Uberlingen Germany). 9 1 /C2924. Viillkopf U. Modern application of ICP-MS (Bonden- seewerk Perkin-Elmer GmbH Postfach 101 164 D-7770 Uberlingen Germany).91/C2925. Gomez A. Dorado M. T. Gutidrrez I. Application of the ablation-ICP technique to the analysis of Fe-V based products (Cent. Nac. Invest. Metal. Avda. Gregorio del Amo Madrid 8 Spain). 91/C2926. Gpez-Molinero A. Anzano J. M. Martinez M. C. Castillo J. R. Determination of erbium in optic fibre forerunners by ICP-AES (Dpto. Quim. Anal. Fac. Cienc. Univ. Zaragoza Zaragoza 50009 Spain). 91/C2927. Pintor R. Villarreal A. Upez-Molinero A. Castillo J. R Multi-elemental determination in geological material by inductively coupled plasma spectrometry (Opto. Quim. Anal. Fac. Cienc. Univ. Zaragoza Zaragoza 50609 Spain). 9 1 /C2928. Garcia N. Sanchez M. I. L u h M. P. Frias M. The use of ICP-AES and UV-visible spectrophotometry to deter- mine Fell and Fell1 in silicate rocks (Inst. C.C. Eduardo Torroja (C.S.I.C.) C/Serrano Galvache s/n Madrid 28033 Spain).
ISSN:0267-9477
DOI:10.1039/JA991060221R
出版商:RSC
年代:1991
数据来源: RSC
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6. |
Glossary of abbreviations |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 228-228
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摘要:
228R JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991. VOL. 6 Glossary of Abbreviations Whenever suitable elements may be referred to by their chemical symbols and compounds by their formulae. The following abbreviations are used extensively in the Atomic Spectrometry Updates. a.c. AA AAS AE AES AF AFS AOAC APDC ASV CCP CMP CRM cw d.c. DCP DMF DNA EDL EDTA EDXRF EIE EPMA ETA ETAAS ETV EXAFS FAAS FAB FAES FAFS FI Fr FTMS GC GD GDL GDMS Ge(Li) HCL h.f. HG HPGe HPLC IAEA IBMK ICP ICP-MS IR alternating current atomic absorption atomic absorption spectrometry atomic emission atomic emission spectrometry atomic fluorescence atomic fluorescence spectrometry Association of Official Analytical Chemists ammonium pyrrolidinedithiocarbamate (ammonium pyrrolidin-1-yldithioformate) anodic stripping voltammetry capacitively coupled plasma capacitively coupled microwave plasma certified reference material continuous wave direct current d.c.plasma N N-dimethy Iformamide deoxyribonucleic acid electrodeless discharge lamp ethylenediaminetetraacetic acid energy dispersive X-ray fluorescence easily ionizable element electron probe microanalysis electrothermal atomization electrothermal atomic absorption electrothermal vaporization extended X-ray absorption fine structure flame AAS fast atom bombardment flame AES flame AFS flow injection Fourier transform Fourier transform mass spectrometry gas chromatography glow discharge glow discharge lamp glow discharge mass spectrometry lithium-drifted germanium hoilow cathode lamp high frequency hydride generation high-purity germanium high-performance liquid chromatography International Atomic Energy Agency isobutyl methyl ketone (4-methylpentan-2- inductively coupled plasma inductively coupled plasma mass spectrome- try infrared spectrometry spectroscopy one) IUPAC LC LEI LMMS LTE MECA MIP MS NAA NaDDC NIES NIST NTA OES PIGE PIXE PMT PPm FYTFE r.f.REE(s) RIMS RM RSD S/B SEC SEM SFC Si(Li) SIMAAC SIMS SFr SR SRM SSMS STPF TCA TIMS TLC TOP0 TXRF u.h.f. uv VDU vuv WDXRF XRF PFb QC International Union of Pure and Applied liquid chromatography laser-enhanced ionization laser microprobe mass spectrometry local thermal equilibrium molecular emission cavity analysis microwave-induced plasma mass spectrometry neutron activation analysis sodi um die thy Idi thiocarbamate National Institute for Environmental National Institute of Standards and nitrilotriacetic acid optical emission spectrometry particle-induced gamma-ray emission particle-induced X-ray emission photomultiplier tube parts per billion parts per million pol ytetrafluoroethylene quality control radio frequency rare earth element(s) resonance ionization mass spectrometry reference material relative standard deviation signal to background ratio s ize-exc lusion chromatography scanning electron microscopy supercritical fluid chromatography lithium-drifted silicon simultaneous multi-element analysis with a continuum source secondary ion mass spectrometry signal to noise ratio synchrotron radiation Standard Reference Material spark source mass spectrometry stabilized temperature platform furnace trichloroacetic acid thermal ionization mass spectrometry thin-layer chromatography trioctylphosphine oxide total reflection X-ray fluorescence ultra-high-frequency ultraviolet visual display unit vacuum ultraviolet wavelength dispersive X-ray fluorescence X-ray fluorescence Chemistry Studies Technology
ISSN:0267-9477
DOI:10.1039/JA991060228R
出版商:RSC
年代:1991
数据来源: RSC
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7. |
Conference reports |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 345-348
Julian F. Tyson,
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JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991 VOL. 6 345 Conference Reports Third Winter Conference on Flow Injection Analysis January AZ USA 6th-9th 1991 Phoenix One of the interesting features of the flow injection techniques is that it provides common ground for analyti- cal chemists who might otherwise not consider themselves to have much in common. Thus the small group of stalwarts who braved the somewhat unseasonable coolness of Phoenix for a few days in January to attend the 3rd Winter Conference on Flow In- jection Analysis found as on previ- ous occasions that they had a lot to talk about. If it is possible to have established conference traditions at only the third attempt it would be tempting to report that the conference opened in the traditional manner with a lecture from Jarda RfiiiEka (University of Washington Seattle WA). Professor RdiiEka managed yet again to com- bine a thoughtful overview of flow analysis with some novel research from the extremely active group that he co-directs with Gary Christian.His unfailing enthusiasm for the pos- sibilities of flow analysis is hard to resist and his view that flow injection (FI) provides the interface between solution chemistry and instrumenta- tion surely identifies a major direc- tion for the development of analytical chemistry. A direction not just for research with the consequent impli- cations for the practice of analytical chemistry but intriguingly also a direction for the teaching of analyti- cal chemistry. Maybe the time is right for the replacement of the ‘quant’ and ‘instrumental’ courses (typically taught in US institutes of higher education) by courses that teach ana- lytical chemistry through the medium of flow techniques.The recent devel- opments in the field of FI for atomic spectrometry culminating in the appearance of the FIAS 200 unit from Perkin-Elmer were cited as a good example of how FI techniques provided such an interface. Sequential injection and ‘sinusoi- dal flow’ were also discussed to the delight of those practitioners who always maintained that FI would only achieve its true potential once the present rotary injection valve and peristaltic pump were replaced by more reliable components. The use of a stream switching valve to sequenti- ally aspirate wash sample and reag- ent solutions by the withdrawal of the plunger in a syringe pump represents a new concept in that the resulting FI peak produced on reversal of the plunger direction results from the interdispersion of sample and reagent at just a single boundary (conven- tional FI peaks are formed by the overlap of front and rear boundaries of the injected sample) under the hydrodynamic regimes produced by the variable flow of the piston pump.The theme of reliability of compo- nents was continued in subsequent talks concerned with process analysis and control. Duane Wolcott (Dow Chemicals Plaquemine LA) pre- sented results obtained with a versa- tile propulsion unit constructed from a number of FMI pump heads driven from a single stepper motor. A num- ber of operations could be imple- mented including on-line dilution and liquid-liquid extraction by vary- ing the volume per stroke and run- ning the pumps either in or out of phase.With up to 800 steps per stroke of the pump head precise control over fluid metering was pos- sible. Don Olson (Shell Develop- ment Houston TX) described his organization’s approach in develop- ing a ‘generic’ process analyser based on FI methodology. The versatility of the technique in the laboratory situa- tion was illustrated by the design of a manifold for the determination of five sulphur species in aqueous samples. The benefits of the reverse configu- ration (in which the sample is the carrier stream) were nicely illustrated by Ernie Boughman (Amoco Naper- ville IL) who described a process analysis system in which the pressure in the sample line was used for propulsion.The reagent was also de- livered from pressurized reservoirs and injected via a 1 0-port slider valve to produce two reagent zones with a sample zone trapped in between. Mixing was assisted by the use of a helical insert. The session on FI ap- plications to process streams finished with Karl Schick’s (FIAtron-Eppen- dorf Madison WI) description of a system for the determination of H2S and C02 based on gas-phase molecu- lar absorption. After liberation of the gases by the addition of acid HIS is determined by UV absorption and C02 by IR absorption. In addition a total alkalinity parameter could be determined via the enthalpy of neu- tralization measured with a thermis- tor detector. An indication of the maturity of FI methodology and of the impact on standard methods was provided by Scott Steig (Lachat Instruments Milwaukee WI) who described the work of a Joint Task Group of the Joint Editorial Board of Standard Methods for the Examination of Water and Wastewater to create a new section entitled ‘Automatic Continuous Flow Analysis’.He dis- cussed the difficulties that had arisen as a result of the writing of methods around the characteristics of one par- ticular manufacturer’s instrumenta- tion and proposed a set of generic manifold diagrams for the ‘big eight determinations of environmental lab- oratories’ (chloride fluoride ammo- nia total oxidized nitrogen nitrite phosphate silicate and sulphate). It was pointed out that The Environ- mental Protection Agency has already approved FI as an option in continu- ous-flow methodology.A critical examination of one of the fundamental differences between the two types of methodology was then made by Charles Patton (US Geologi- cal Survey Arvada CO) who pointed out that it was possible to obtain reproducible timing in a gas-seg- mented stream. This can be achieved by the use of the so-called air-bar technique (adding air bubbles to the analytical stream in phase with the roller lift-off). This technique can be adapted to FI to give a gas-segmented reactor which has mixing character- istics that are superior to the open tubular reactor and allows an en- hanced sample throughput to be achieved. Could the bubble be poised for a ‘come-back’? In the pursuit of improved detec- tion limits Dave Curran (University of Massachusetts Amherst MA) elec- trified his audience with the perf‘orm- ance of a simple cross correlation technique.A single-line manifold was used in which a reference signal was first generated with a high concentra- tion of analyte. This signal was stored and played back in real time synchro- nized with the analyte signal. The cross correlation (essentially multipli- cation and time averaging) produced a reduced sensitivity but this was offset by the noise reduction to such an extent that well over an order of346 magnitude improvement in the detec- tion limit for the amperometric determination of dopamine was obtained. There would seem to be no reason why this technique could not be applied to other types of detector. Another aspect of the use of com- puters in the pursuit of improved analytical performance was provided by Terry Tougas (Polaroid Waltham MA). A multi-component spectro- photometric procedure had been fully automated including the production and display of control charts and transfer of the results to VAX-based corporate databases.The need for automation in the provision of ana- lytical information in support of the running of a nuclear power station was illustrated by Mike Whitaker (Westinghouse Savannah River Com- pany Aiken SC) who described an approach to the measurement of pH in unbuffered solutions. A spectro- photometric procedure based on the indicator Resazurin has achieved precisions of less than 1% RSD over the pH range 4.7-5.3. The first day concluded with a description by Steve Hoke (US Army Biomedical Research and Develop- ment Laboratory Frederick MD) of a field instrument for monitoring the concentration of potentially toxic gases.Such gases are emitted not only by various incinerators and electrical fires but also by various military weapons. A rapid extraction system based on a continuous impinger had been interfaced with an FI system with potentiometric detection to give near real-time response for a number of constituents. The extent to which FI procedures are now part of analytical atomic spectrometry was reviewed by Julian Tyson (University of Massachusetts Amherst MA) in the first lecture of the next session. In particular the use of solid-phase reagents for analyte preconcentration and matrix removal has attracted considerable interest and a substantial number of publica- tions (over 60) have appeared that deal with such procedures.Dr. Tyson also outlined recent work in his own research group concerned with (a) matrix removal for hydride genera- tion by using a solid-phase reagent; (b) the use of a supercritical fluid carrier stream; and (c) the on-line digestion of the organic matrix of a slurry sample. A number of FI atomic spectrome- try topics were covered in more detail in the following papers. The problems of determining tin by hydride genera- tion procedures were discussed by Randy Hergenreder (Perkin-Elmer Norwalk CT). It was shown that JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991 VOL. 6 most of the problems arose from the presence of other hydride forming elements in the sample matrix when a heated quartz tube atomizer was used.A considerable improvement in performance was obtained when the generated hydride was collected in a graphite furnace that had been pre- treated by the injection of a solution of palladium. A characteristic con- centration similar to that obtained for direct introduction of an aqueous tin standard into the furnace was obtained. This procedure could well become the standard method of de- termining hydride forming elements. The topic of chemical vapour gen- eration was continued in the presen- tation by Ed Paxki (Bondar-Clegg North Vancouver British Columbia) who entertained his audience with an account of how a laboratory faced with the requirement to analyse large numbers of mineral samples for mer- cury had developed an automated FI cold vapour atomic absorption spec- trometer.The instrument could handle between 1000 and 1500 deter- minations per 24 hour day once a sample solution had been obtained. A dynamic range of between 0.5 and 5000 pg I-’ was obtained for a 200 pl sample solution. The problems that a laboratory of this sort faces were nicely illustrated by the disastrous effects of the atternpted analysis of a sample with an unexpectedly high gold content. The appearance of a purple coating of colloidal gold on the interior of the flow lines heralded an extended shut-down and some equally colourful language to describe Dr. Paski’s feelings about his secre- tive client. There are good commer- cial reasons for not disclosing the full details of the instrument’s construc- tion and operation which means unfortunately that the results of another first-rate piece of research in instrumental analytical spectroche- mistry will not find their way into the open literature.The on-line derivatization and ma- trix isolation theme was continued with a description by Herb Lancaster (University of Washington Seattle) of a sorbent extraction system coup- led to a flame atomic absorption spectrometer. In this procedure a chelating agent is first sorbed onto a solid reversed-phase chromatography stationary phase (typically CI8 ma- terial). The sample solution was then passed and the analyte species re- tained by the modified solid-phase reagent. Elution was effected by changing the polarity of the solvent and reversing the direction of fluid flow.It was pointed out that the design of manifolds for solid-phase extraction was often limited by a ‘legacy from chromatography’ namely that the system should con- tain a fully-packed column and use unidirectional flow. However by re- ducing the amount of solid phase in the column a kind of ‘fluid-bed’ was produced which although increasing the dispersion coefficient slightly avoided the problems of flow reduc- tion which often occur in this type of manifold as the back-pressure due to the column gradually increases with use. The versatility of FI procedures was illustrated by Elo Hansen (Tech- nical University Lyngby) who de- scribed an amplification procedure based on the use of co-immobilized enzymes. The manifold was concep- tually similar to that described for the preconcentration of trace elements for detection in atomic spectrometry but the chemistry was tailored to the determination of traces of pyruvate or lactate.The enzyme reactor con- tained both lactate oxidase and lac- tate dehydrogenase so that the pro- duct of an enzyme catalysed reaction was a substrate for the second system which regenerated the reactant. In the particular system chosen the contin- uous cycle produced a considerable excess of the co-product hydrogen peroxide which was detected by the chemiluminescence generated from the oxidation of luminol (catalysed by Fe*I1). Amplification factors of be- tween 100 and 1 50 were possible. The importance of enzymes and the need to monitor inhibitors was brought into sharp focus by Jim Hungerford (US Food and Drug Administration Bothell WA) who described the symptoms of Scombroid poisoning a reasonably common problem arising from the improper storage of certain foods especially cheese and fish.Vic- tims show typical allergic reaction symptoms due to disruption of con- trol mechanisms for the regulation of the histamine levels throughout the body. Diamine oxidase is one of the enzymes involved and an assay for possible toxic effects was constructed around the interruption by sample components of the steady-state en- zymic destruction of histamine. Fluo- rescence detection was used to moni- tor the reaction product between his- tamine and phthalaldehyde. Fluorescence detection was also used in the system described by Tho- mas Gubeli (University of Washing- ton Seattle) for the kinetic determi- nation of a proteolytic enzyme widely used in the detergent industry.The sinusoidal flow and sequential injec- tion procedures described earlier by Jarda REiiEka were used as the basis for a fully automated stopped-flow method. The substrate used was aJOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 1991 VOL. 6 347 tripeptide containing 7-amino-4- methyl coumarin which when re- leased by the enzyme reaction had a fluorescence intensity 850 times that of the tripeptide. The claim of luminescence to be a detection mode ideally suited to flow injection presentation is only beaten by that of electrochemical procedures which are undoubtedly enjoying a new lease of life thanks to flow injection.The use of a nickel oxide potentiometric electrode for the de- tection of alcohols amino acids and carbohydrates was described by Cal- vin Huber (University of Wisconsin Milwaukee WI) who stated that FI provided an ideal method of control- ling the electrode environment dur- ing the pre-treatment stage. The sur- prising versatility of biologically modified electrodes was illustrated by the quick-fire presentation of numer- ous examples by Joe Wang (New Mexico State University Las Cruces NM) who has continued to raid the fruit and vegetable world for enzyme- containing tissue with which to fabri- cate electrodes. In this chapter of what is a fascinating and continuing story bananas potatoes papaya and zuccini made an appearance some- times in intimate contact with the electrode material (as with the bana- na-carbon paste electrode for the determination of dopamine) and sometimes as an upstream bioreactor (mounted in the tube wall) with downstream amperometric detection.The final day of the conference opened with an overview from Elo Hansen of whether FI is exploited optimally. With the FI literature standing at some 3300 publications in 1990 it was clear that many uses of FI centered on the potential for the development of automated chemical analysis procedures. However Dr. Hansen agreed that the real power of FI lies in the unique possibilities of the methodology which go beyond the development of continuous flow versions of previously devised batch chemical procedures. A number of examples of the unique FI features several of which involved atomic spectrometry were cited in support of this thesis.These included (a) the ability of an FI sample introduction system for flame and plasma based techniques to deliver samples with high dissolved solids or with high organic solvent contents; (b) the pos- sibility for time-based measurements such as peak width or gradient dilu- tion; and (c) the implementation of various indirect procedures. In addi- tion to the atomic spectrometry pos- sibilities features concerned with ki- netic characteristics such as kinetic marking kinetic discrimination at electrode and other sensor surfaces and stopped flow were discussed. The ability of an FI system to synthe- size reagents (possibly unstable ones) when needed was also discussed. It would seem there are still some un- derexploited areas and perhaps even some as yet undiscovered possibili- ties for FI.The discussions took a more practi- cal turn following the presentation by Gil Pacey (Miami University Ox- ford OH) concerning a new device for producing mixing at confluence points. This discussion suggested that there is still some difficulty in visualizing the scale of the longitudi- nal and radial gradients. Maybe flow injection should be demonstrated on more occasions (see Tyson J. F. Fresenius 2. Anal. Chem. 1987,329 675). A good example of the exploitation of the kinetic character of FI was provided by Mike Straka (Perstorp Analytical Herndon VA) who de- scribed a method for the determina- tion of total cyanide. Gas diffusion was first used (an illustration of the safe sample handling environment provided by an FI manifold) to sepa- rate the analyte which was then quan- tified by measurement of an unstable intermediate instead of the stable final product of the reaction between cyanide isonicotine acid and 3-me- thyl- 1 -phenyl-5-pyrazolone. As the full formation of the product is rela- tively slow the throughput was in- creased when the intermediate was monitored.Further utilization of the precise kinetic nature of fluid flow was provided by Richard Taylor (University of Washington Seattle WA) who presented results for the flow injection coulometric titration of acids and bases over 3-4 orders of magnitude of concentration. The wide working range was achieved by on-line dilution in a well-stirred tank.End-point detection was by remote spectrophotometry with fibre-optic light guides. The dilution chamber titrant generation chamber and detec- tor flow cell were integrated into one unit. Precisions of between 1 and 3% RSD were obtained. In the final presentation Adrian Wade (University of British Colum- bia Vancouver) presented results for the automated optimization of a spectrophotometric method for the determination of sulphide. The diffi- culties that an automated simplex optimization procedure could en- counter were nicely illustrated and the importance of not neglecting some basic chemistry stressed. The full range of the factor space for reagent concentrations including a region in which a precipitate formed which not unnaturally gave very high absorbance readings.The prob- lem was recognized by constructing a response surface map from a 7x7 experimental grid. The procedure eventually developed was applied to the analysis of wood pulp liquors. In addition to the formal presenta- tions and discussion the excellent venue chosen by the organizers (and the somewhat atypical inclement weather) ensured that there was plenty of opportunity for informal discussion among delegates as well as an opportunity to view equipment in a small exhibition mounted by Per- kin-Elmer Lachat and FIAtron- Eppendorf. One outcome of this dis- cussion was that the fourth Winter Conference on Flow Injection Analy- sis will take place in 1992. To accom- modate the burgeoning interest in the flow injection-atomic spectrometry combination the meeting will be held on January 12th- 14th immediately following the 1992 Winter Confer- ence on Plasma Spectrochemistry (to be held in San Diego January 6th-11 th 1992) although the venue will again be Phoenix.Julian F. Tyson University of Massachusetts Amherst MA USA348 JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 Atomic Spectrometry Updates Editorial Board Meeting and Scientific Symposium March 27th-28thY 1991 Polytechnic South West Plymouth UK For those of us lucky enough to arrive on the evening prior to the meeting the proceedings could not have begun in a better fashion than the splendid meal to which we were treated at a Spanish restaurant in Plymouth’s his- toric Barbican area. When Neil Bar- nett was in Plymouth this was one of his favourite haunts one can only speculate about the dive in profits they must have suffered since his departure to Melbourne! The main business of the first day was the 25th meeting of the ASU (formerly ARAAS) Editorial Board.Discussions principally concentrated on reports from the executive mem- bers and reports from the six review group co-ordinators with special praise bestowed upon Steve Hill and David Littlejohn for the success of their groups in establishing the two new reviews covering firstly atomic emission and secondly atomic ab- sorption and fluorescence. Some con- cern was voiced over the sheer vol- ume of abstracts now being covered but if the reviews are to be thorough it is difficult to see how this can be avoided. One suggestion was to be more selective about the inclusion of conference abstracts particularly as there is often many a slip ‘twixt abstract and paper’.The day culminated in a hazard- ous journey across the waters to Cornwall and a sumptuous Board Dinner held in a converted coastal fort overlooking the entrance to the English Channel. Entertain- ment was provided by John Price who gave an amusing overview of the first 25 years of ARAAS/ASU. Retirement awards were given to Alan Ure David Littlejohn and Les Ebdon. The scientific symposium was en- titled ‘Alternative Plasma Sources’ and began with a fascinating lecture by Ramon Barnes on the develop- ment of the microwave-induced plasma which has led to the recent introduction of a commercial GC- MIP an instrument that has the considerable attraction of being ap- plicable to the analysis of non-metals.The second part of Professor Barnes’ talk concentrated on a new ICP confi- guration i.e. the sealed ICP. In this the discharge is sealed in a closed quartz container; such a design en- hanced sensitivity over the normal flowing gas ICP. The second presentation by John Dean was of an elegantly designed glow discharge cell which was mounted in the burner compartment of an atomic absorption spectro- meter. The device is being applied to the determination of nickel in steels. There then followed a review from David Littlejohn of progress at Strathclyde and elsewhere in FANES. Although problems exist particularly with calibration where internal standards often have to be used the potential of the technique was apparent particularly for the determination of non-metals.Cur- rent detection limits for FANES lie between those for ETAAS and ICP- AES. Two entertaining talks either side of lunch from Janet Armstrong and Mike Thompson concentrated on two of the more popular plasma sources the DCP and the ICP. Janet gave an overview of environmental analysis using DCP whilst Mike Thompson re-defined the calendar in outlining how the ICP has got to where it is now. The second overseas speaker was Jean-Michel Mermet who in his inim- itable style once again gave us plenty of food for thought this time on the subject of laser produced plasmas an idea first postulated in 1962. How- ever progress has been slow and development is still at the early stage. Nonetheless the technique promises local analysis of solid samples at very competitive detection limits. The uti- lization of fibre-optics makes on-line detection feasible. In the caboose was the third over- seas speaker Ben Fairman from Oveido University. Going by the aerial ballet performed by a number of his slides Ben must have upset the god of conference projectors. Despite major difficulties he persevered with his presentation of sample introduc- tion phenomena using DCP. Select- ing kaolin slurries as samples he used computerized tomography to map spatially the plasma and identify areas of maximum emission. In conclusion one must congratu- late Steve Hill and the staff in Plym- outh for their successful organization of the meeting a success which bodes well for the 6th BNAAS meeting in 1992 for which Polytechnic South West is also the venue. Simon Branch Rank Hovis MacDougalr‘ Research and Engineering Ltd. The Lord Rank Research Centre Lincoln Road High Wycombe Buckinghamshire UK
ISSN:0267-9477
DOI:10.1039/JA9910600345
出版商:RSC
年代:1991
数据来源: RSC
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8. |
Book review |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 348-349
J. R. Bacon,
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摘要:
348 JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 Book Review Continuous-Flow Fast Atom Bom- bardment Mass Spectrometry Edited by Richard M. Caprioli. Pp. x+189. Wiley. 1990. Price f27.50. ISBN 0 471 92863 1. This book is based on a workshop entitled Continuous-Flow FABMS held in November 1989 at Annapolis MD USA and is aimed primarily at workers new to the technique and requiring sufficient detail to be able to use and apply the procedure. Of necessity it 'is restricted to topics presented at the workshop but these appear to have been well chosen for they cover a wide range of applica- tions. The authors generally present their own experience of the technique with the result that coverage is not necessarily comprehensive. This ap- proach has considerable value how- ever as it is less formal and intro- duces the reader to the problems actually encountered and the means of overcoming them.Some seven authors plus additional contributors have written eight chap- ters each of which covers the opera- tional aspects applications and spe- cific experiences in application to particular analytical tasks. The whole book is based on examples and each chapter gives details of instrumenta-JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 349 tion and analytical methodology rele- vant to a particular application. Of particular importance is that difficul- ties and disadvantages have not been overlooked. The first chapter introduces the reader to aspects of design and oper- ation and gives details of individual designs of probe.Special attention is given to the need to achieve a stable operation and a comparison is made with the standard FAB technique. The next two chapters cover aspects relevant to trace analysis and quanti- tative analysis of polar organic com- pounds the latter tending to concen- trate on solutions adopted by the authors in order to overcome particu- lar problems encountered. The remaining chapters are orien- tated more to applications of the technique and cover direct analysis of biological processes LC-MS CZE-MS analysis of low-polarity substances and various other applica- tions. Information on instrumentation and probe design is included in each chapter in particular those on LC- MS and CZE-MS which consider the interface between separation system and MS. In general the applications are to the determination of large biomolecules but they cover a wide range including the on-line measure- ment of drug levels in live animals and applications of tandem MS. In most respects this is an attrac- tive book. It is of manageable size yet is full of valuable and relevant infor- mation laid out in a well-ordered style. It is a book that could be read cover-to-cover or used as a reference to a particular application. Although the information is over 18 months old this book can be recommended especially considering the reasonable cost. J. R. Bacon The Macaulay Land Use Research Institute Craigiebuckler Aberdeen AB92QT UK
ISSN:0267-9477
DOI:10.1039/JA9910600348
出版商:RSC
年代:1991
数据来源: RSC
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9. |
Conferences and meetings |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 349-352
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PDF (425KB)
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摘要:
JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 349 Conferences and Meetings 1991 Autumn Meeting September 24-26 199 1 University of York York UK The first circular for the 1991 Au- tumn Meeting of The Royal Society of Chemistry has been produced by the organizing committee. In this the Society’s 150 Anniversary year the meeting is being held at the Univer- sity of York from lunchtime on Tues- day 24th September to lunchtime on Thursday 26th September with parti- cipants foregathering on the morning of Tuesday 24th September. Topics covered during the meeting will be Chirality; Dynamics and Ster- eochemistry in Inorganic Chemistry; New Chemistry Curricula for the 16- 19 Age Range; Research Practice and Performance in Chemical Educa- tion; How Can Management Best be Taught to Chemists?; Spectroscopy in Environmental Science; The Chemi- cal Industry-Friend to the Environ- ment?; Selective Approaches in Or- ganic Synthesis; and Recent Develop- ments in Gas Kinetics.Each of the sessions will include invited lectures and some have sub- mitted poster and other oral contri- butions. The Dalton and Perkin Divi- sions are planning to hold Council meetings during the course of the meeting. Social events during the meeting will include a Reception at the University on the Tuesday and a Conference Dinner on the Wednes- day. The expected registration fee for the meeting will be €30 (exclusive of VAT) with a daily registration fee of €18 (exclusive of VAT); for all stu- dents who are members of the So- ciety the registration fee will be waived.The accommodation charge for the two day period (half board dinner bed and breakfast) will be around €45 (exclusive of VAT). Further information is now avail- able please contact Dr. John F. Gib- son The Royal Society of Chemistry Burlington House London W 1 V OBN UK. Telephone 071 437 8656; telefax 071 437 8883. Thirtieth Annual Eastern Analytical Symposium and Exposition November 1 1 - 15 199 1 Garden State Convention and Exhibit Center and the Somerset Hilton Hotel Somerset NJ USA The 199 1 Eastern Analytical Sympo- sium (EAS) programme will feature an international gallery of speakers in the most critical areas of the analyti- cal and allied sciences. In keeping with tradition the programme will include award symposia honouring the recipients of the EAS Award for Outstanding Achievements in the Field of Analytical Chemistry the EAS Award for Achievements in Chromatography the EAS Award for Achievements in the Field of Near- Infrared Spectroscopy the EAS Award for Achievements in the Field of Magnetic Resonance the American Microchemical Society Be- nedetti-Pichler Memorial Award and the New York Section of the Society for Applied Spectroscopy Award Medal.Central to the success of the 1991 EAS Technical Program are the con- tributed and invited papers which will be presented in both oral and poster formats. The 1991 Exposition will feature 250 manufacturers exhibiting the latest in analytical technology with easy a c e s to the technical session which will be held on the same levels of the Garden State Convention and Exhibit Center.The Exposition opens at 12.00 on Monday and closes at 14.00 on Thursday. Complete information regarding the Exposition can be obtained from the Exposition Director Mr. Robert W. Bardoux Sr. 4704 Bert Drive Monroeville PA 15146 USA. Tele- phone (412) 372-8965 or telefax (412) 372-6748 or contact the EAS Hotline on (302) 453-0785. 13th NASTEC Nordic Atomic Spectroscopy and Trace Element Conference February 10- 14 1992 Geilo Norway This traditional conference will once again provide a forum for Nordic trace element scientists for personal contact and exchange of experience. Sessions The scientific programme opens Tuesday morning (09.00) and closes Friday after lunch. The programme consists of invited lectures free oral presentations and posters.Poster pre- sentations will be given equal promi- nence and ample time will be al- lowed for discussions. Exhibition An exhibition of instruments and accessories will be arranged in the immediate vicinity of the lecture hall. Companies interested in participat- ing in the exhibition should fill in the preliminary registration form or con- tact the organizing committee.350 JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 Submission of abstracts The Organizing Committee cordially invites you to submit an abstract of original research related to the devel- opment and application of analytical techniques for trace element analysis in a broad sense. Invited lecturers Invited speakers include Professor E. H. Hansen (Technical University of Denmark) recent advances in FIA; Dr.C. Haraldsson (Chalmers Uni- versity of Technology Sweden) re- cent advances in ICP-MS; Dr. B. Bjorquist (Espoo Research Centre Finland) HPLC and IC in inorganic trace element determination; Dr. R. Bye (University of Oslo Norway) recent advances in hydride genera- tion atomic spectrometry; Professor K. J. Irgolic (Karl-Franzens Uni- versitat Austria) determination of organometallic species with element- specific detectors; Dr. B. Radziuk (Perkin-Elmer Germany) present sta- tus and future development within ETAAS; and Professor E. Steinnes (University of Trondheim Norway) tracer techniques in environmental and biological studies. Accommodation and transportation The conference site will be the High- land Hotel Geilo (telephone 47-67-85600) where rooms for par- ticipants are reserved.The hotel of- fers a variety of indoor and outdoor facilities (swimming pool sauna solarium cross country and slalom/ downhill skiing facilities). Registration fee Registration not later than November 1 NOK 1 500; for registered stu- dents NOK 750. Registration after November 1 NOK 2 000. The regis- tration fee includes an abstract book and social programme. Social programme An informal welcome reception at the Highland Hotel will be arranged Monday evening February 10. The symposium dinner is scheduled for Thursday evening February 13 1992. A special social event is planned for Wednesday afternoon. Correspondence For further information contact NASTEC Att. Salbu Isotope and Electronmicroscopy Laboratories Agricultural University of Norway P.O.Box 26 N-1432 Aas-NLH Nor- way. Telephone 47-9-94 83 50; tele- fax 47-9-94 83 59. 43rd Pittsburgh Conference and Ex- position on Analytical Chemistry and Applied Spectroscopy March 9-13 1992 New Orleans LA USA The 1992 Pittsburgh Conference and Exposition will be held at the New Orleans Convention Center New Or- leans. Technical papers will be presented on analytical technology materials characterization environmental monitoring laboratory management biochemical and clinical applications and related areas. The conference will feature several technical sessions in which awards will be presented to distinguished scientists. The award symposia planned for Pittcon '92 include the Pittsburgh Analytical Chemistry Award; Keene P.Dimick Award; James L. Waters Symposium; Wil- liams-Wright Industrial Spectro- scopist Award; Pittsburgh Spectro- scopy Award; Charles N. Reilley Award; and the Dal Nogare Award. Registration housing employment bureau and activities information will be sent out in October 199 1. For further general information contact Pittsburgh Conference De- partment CFP 300 Penn Center Bou- levard Suite 332 Pittsburgh PA The exhibition will feature the fin- est and most complete exhibition of modern laboratory equipment in- strumentation supplies and services available. 15235-5503 USA. For further information or to res- erve exhibition space please contact W. Richard Howe Exposition Chair- man Pittsburgh Conference 300 Penn Center Boulevard Suite 332 Pittsburgh PA 15235-5503 USA.Anatech '92 3rd International Sympo- sium on Analytical Techniques for Industrial Process Control April 6-8 1992 Atlanta GA USA The symposium will be held at the Lake Lanier Islands Hotel a short distance north of Atlanta. This symposium was previously held in The Netherlands (in 1986 and 1990) and like its European predeces- sors this first symposium of Anatech in the USA will focus on the latest developments in process analytical chemistry for an interdisciplinary au- dience. Some of the techniques cur- rently in use in production environ- ments and contributing to process optimization are spectroscopy chro- matography automated wet chemical analysis advanced computing etc. and new emerging techniques. Participants wishing to present a paper should fill out an abstract form (which can be obtained from the conference organizers); the deadline for submission of abstracts is Novem- ber 1 1991.An exhibition will be arranged in conjunction with the Conference. As with previous Anatech meet- ings an all-inclusive package is of- fered which covers the registration fee all accommodation and meals a welcome reception banquet and a copy of the proceedings. For further information contact Anatech '92 Infoscience Services Inc. 3000 Dundee Road Suite 313 Northbrook IL 60062 USA. Tele- phone (708) 29 1-9 16 1 ; telefax (708) 291-0097. BERM-5 Fifth International Sympo- sium on Biological and Environmental Materials May 1 1-14 1992 Novotel Am Euro- paplatz Aachen Germany The Fifth Symposium on Biological and Environmental Materials will continue this series being held ap- proximately every two years. Activi- ties at the Fifth Symposium are ex- pected to broaden the discussions and focus on more specific aspects of research on problems and progress in projects discussed at the Fourth Sym- posium held in Florida in 1990.Topics The major aim of this Symposium series is to bring together efforts in the production study and use of Reference Materials in the analytical biological biomedical clinical envi- ronmental and nutritional communi- ties. Call for papers Preliminary titles of papers are re- quested by October 199 1. Abstracts of papers should be submitted by February 1 1992. For further information contact Dr Wayne R. Wolf BERM-5 Nutri- ent Composition Laboratory United States Department of Agriculture Beltsville Maryland 20705 USA.Telephone (30 1) 344-2927; telefax (301) 344-2314.JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY. AUGUST I99 1. VOL. 6 35 1 Sixth Biennial National Atomic Spectroscopy Symposium will be held at Polytechnic South West Plymouth UK 22-24 July 1992 The symposium will provide a forum where interesting and useful applications of atomic spectros- copy can be reported and discussed. In addition to plenary invited and submitted lectures a particu- lar feature of the meeting will be the presentation of posters. There will also be an exhibition and a social programme for delegates and their guests. Scientific programme will include Plenary Lecturers- M.W. Blades (Vancouver BC Canada) B.V. L’vov (Leningrad USSR) J.W. McLaren (Ottawa Ontario Canada) K.Niemax (Dortmund Germany) B.L. Sharp (Lmghborough UK) Invited Lecturers- J. S . Crighton (Sunbury-on-Thames UK) H. Falk (Kleve Germany) S.J. Hill (Plymouth UK) D. Littlejohn (Glasgow UK) C. McLeod (Shefield UK) G. Schlemmer (Uberlingen Germany) P. Stockwell (Sevenoaks UK) J.F. Tyson (Amherst MA USA) J.G. Williams ( E g h UK) A.M. Ure (Glasgow UK) This meeting is organized by the Atomic Spectroscopy Group Analytical Division of The Royal Society of Chemistry. Further information can be obtained from the Chairman of the organizing committee Dr S. J. Hill Department of Environmental Sciences Polytechnic South West Drake Circus Plymouth Devon PL4 8AA UK.352 Second Rio Symposium on Atomic Absorption Spectrometry June 21-28 1992 Rio de Janeiro Brazil The second Rio Symposium will be divided into two parts.In the first part the emphasis will be on furnace flame and hydride techniques and will be held at the Pointificia Univer- sidade Cat6lica do Rio de Janeiro June 2 1-24. The second part will be devoted entirely to furnace atomic absorption spectrometry and will be held at the Nas Rocas Club Hotel in Buzois located 154 km north of the city of Rio de Janeiro. Part I The programme will include invited lectures (50 min) oral pre- sentation of papers (20 min) and posters covering the following top- ics introduction of samples; cou- pling with flow injection; instru- ment development; analytical qual- ity assurance; interference studies; application to environmental bio- logical and industrial samples; and speciation. Part 11 The programme will include invited lectures (50 min) and pre- JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL.6 sentation of papers (20 min) cover- ing the following topics atomiza- tion theories and mechanism; tem- perature and atom distribution; surfaces and substrate materials; combined techniques; chemical modification; solid and shiny sampling; and new concepts. Invited speakers Distinguished scientists of the area are being invited to present lectures. Call for papers The organizers invite the submission of an abstract. Titles must be submit- ted with the preliminary application form not later than November 199 1. The deadline for receipt of abstracts is February 15 1992. Registration fee The registration fee is US$ 100.00 for Part I and US$ 100.00 for Part 11. For registered students and accompany- ing persons the fee is US$SO.OO for each Part. Social events A welcome reception (included in the fee) will be held on Sunday evening June 21 1992. A dinner is scheduled for Wednesday evening June 24. Excursions to touristic points in the city of Rio de Janeiro for accompany- ing persons and post-symposium tours will be available. On the island nautical and on-land recreational ac- tivities will be available and are in- cluded in the room prices. Exhibitions Instruments books and materials will be on display during Part I of the symposium. Exhibitors will be given an opportunity to give short explanatory talks about their equip- ment. For further information contact Dr. Adilson J. Curtius Departa- mento de Quimica da PUWRJ Rua Marques de Silo Vicente 225 22.453-Rio de Janeiro RJ Brazil. Telephone (021) 529 9547; telefax (021) 222 2305.
ISSN:0267-9477
DOI:10.1039/JA9910600349
出版商:RSC
年代:1991
数据来源: RSC
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10. |
Papers in future issues |
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Journal of Analytical Atomic Spectrometry,
Volume 6,
Issue 5,
1991,
Page 352-352
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PDF (91KB)
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摘要:
352 JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY AUGUST 199 1 VOL. 6 Future Issues will Include- Comparison of Normal and Low Flow Torches for Inductively Coup- led Plasma Mass Spectrometry Using Optimized Operating Condi- tions-E. Hywel Evans and Les Ebdon Determination of Lead by Hydride Generation Atomic Absorption Spec- trometry With In Situ Concentration in a Zirconium Coated Graphite Tube-Yan Xu-Ping and Ni Zhe- Ming Organic Solvents in Electrothermal Atomic Absorption Spectrome- try-E. Tserovsky and S. Arpadjan Determination of Lead in Soil by Slurry-Graphite Furnace Atomic Ab- sorption Spectrometry With a Fast Temperature Programme-Michael W. Hinds Kathryn E. Latimer and Kenneth W. Jackson Comparison of Refractive Index En- ergy Dispersive X-ray Fluorescence and Inductively Coupled Plasma Atomic Emission Spectrometry for Forensic Characterization of Sheet Glass Fragments-Robert D.Koons Charles A. Peters and Pamela S. Rebbert Quantitative Analysis of Trace Ele- ments in Carbonates Using Laser Ablation Inductively Coupled Plasma Mass Spectrometry-W. T. Perkins R. Fuge and N. J. G. Pearce Analytical Performance Evaluation of a New 40.68 MHz Inductively Coupled Plasma Mass Spectro- meter-Chang J. Park and Kwang W. Lee Rapid Stopped-flow Microwave Di- gestion System-V. Karanassios F. H. Li B. Liu and Eric D. Salin. Tungsten-tube Electrothermal Atom- izer WETA-90. Part 1. Design and Performance of the Atomizer- Vaclav Sychra Jiri Delezal Robert Hlavac Libor Petros Olga Vyskoci- lova Dana Kolihova and Petr Puschel Inserted Injector Tubes for Induc- tively Coupled Plasma Spectro- metry-L.Gervais and Eric D. Salin Study of Precision and Bias in the Measurement of Lead Isotope Abun- dance Ratios by Inductively Coupled Plasma Mass Spectrometry- Michael E. Ketterer Michael J. Pet- ers and Preston J. Tisdale Platform in Furnace Zeeman Atomic Absorption Spectrometric Determi- nation of Arsenic in Beer by Slurry Atomization of Sample Ashes-M. L. Cervera A. Navarro R. Montoro M. de la Guardia and A. Salvador Investigations on the Determination of Chloride and Bromide by Means of Furnace Atomic Non-thermal Excita- tion Spectrometry and Furnace Ionic Non-thermal Excitation Spectro- metry-Klaus Dittrich Bernhard Radziuk and Bernhard Welz Shadow Spectral Filming-A Method of Investigating Electrother- mal Atomization. Part 1. Dynamics of Formation and Structure of the Absorption Layer of Thallium In- dium Gallium and Aluminium Atoms-A. K. Gilmutdinov Y. A. Zakharov V. P. Ivanov and A. V. Voloshin Multi-element Analysis of Ferro- chromium and Ferromanganese by Inductively Coupled Plasma Atomic Emission Spectrometry-Ivan Hlavh- Eek and Irena HlavCEklova
ISSN:0267-9477
DOI:10.1039/JA9910600352
出版商:RSC
年代:1991
数据来源: RSC
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