Application of non-traditional stable isotopes in analytical ecogeochemistry assessed by MC ICP-MS - A critical review

详细信息    查看全文

• 作者：Johanna Irrgeher ; Thomas Prohaska
• 关键词：Analytical ecogeochemistry ; Non ; traditional stable isotopes ; Isotope tracers ; MC ICP ; MS ; Chemical metrology
• 刊名：Analytical and Bioanalytical Chemistry
• 出版年：2016
• 出版时间：January 2016
• 年：2016
• 卷：408
• 期：2
• 页码：369-385
• 全文大小：1,002 KB
• 参考文献：1.Zitek A, Irrgeher J, Prohaska T (2015) Anal Bioanal Chem (this issue)
  2.Naveh Z (2000) Bioscience 50(4):357–361CrossRef
  3.Habfast K (1983) Int J Mass Spectrom Ion Process 51(2/3):165–189CrossRef
  4.Nier AO, Gulbransen EA (1939) J Am Chem Soc 61:697–698CrossRef
  5.Nier AO (1939) J Am Chem Soc 61:697CrossRef
  6.Nier AO (1940) Rev Sci Instrum 11:212–216CrossRef
  7.Nier AO (1947) Rev Sci Instrum 18(6):398–411CrossRef
  8.Assonov S, Prohaska T (2015) Gas source isotope ratio mass spectrometry for the analysis of noble gases. In: Sector field mass spectrometry for elemental and isotopic analysis. The Royal Society of Chemistry, Chap. 17 pp 550–581
  9.Eiler JM (2007) Earth Planet Sci Lett 262(3):309–327CrossRef
  10.Burger S, Vogl J, Kloetzli U, Nunes L, Lavelle M (2015) Thermal ionization mass spectrometry. In: Sector field mass spectrometry for elemental and isotopic analysis. The Royal Society of Chemistry, Chap. 14 pp 381–438
  11.Douthitt C (2008) Anal Bioanal Chem 390(2):437–440CrossRef
  12.Albarède F, Beard B (2004) Rev Mineral Geochem 55(1):113–152CrossRef
  13.Yang L (2009) Mass Spectrom Rev 28(6):990–1011CrossRef
  14.Vogl J (2005) Calibration strategies and quality assurance. In: Nelms S (ed) Inductively Coupled Plasma Mass Spectrometry Handbook, 1st edn. Blackwell Publishing Ltd., Oxford, pp 147–181
  15.Aggarwal JK, Sheppard D, Mezger K, Pernicka E (2003) Chem Geol 199(3):331–342CrossRef
  16.Meija J, Yang L, Mester Z, Sturgeon RE (2012) Correction of instrumental mass discrimination for isotope ratio determination with multi-collector inductively coupled plasma mass spectrometry. In: Vanhaecke F, Degryse P (eds) Isotopic analysis. Wiley-VCH Verlag GmbH & Co, KGaA, pp 113–137CrossRef
  17.Irrgeher J, Prohaska T (2015) Instrumental isotopic fractionation. In: Sector field mass spectrometry for elemental and isotopic analysis. The Royal Society of Chemistry, Chap. 6, pp 107–120
  18.Sahoo SK, Masuda A (1997) Chem Geol 141(1/2):117–126CrossRef
  19.Venzago C, Pisonero J (2015) Glow discharge mass spectrometry. In: Sector field mass spectrometry for elemental and isotopic analysis. The Royal Society of Chemistry, Chap. 13, pp 319–380
  20.Sangely L, Boyer B, de Chambost E, Valle N, Audinot J-N, Ireland T, Wiedenbeck M, Aleon J, Jungnickel H, Barnes J-P, Bienvenu P, Breuer U (2015) Secondary ion mass spectrometry. In: Sector field mass spectrometry for elemental and isotopic analysis. The Royal Society of Chemistry, Chap. 15, pp 439–499
  21.CIAAW (2015) Commission on Isotopic Abundances and Atomic Weights. ciaaw.org.
  22.Holden NE (2014) Nucl Data Sheets 120:169–170CrossRef
  23.Brand WA, Coplen TB (2012) Isot Environ Health Stud 48(3):393–409CrossRef
  24.Fietzke J, Eisenhauer A (2006) Geochem Geophys Geosyst 7(8). doi:10.​1029/​2006GC001243
  25.Mittelstraß J (2005) Technikfolgenabschätzung Theor Prax 14(2):18–23
  26.Nriagu JO, Lawson G, Wong HKT, Azcue JM (1993) J Great Lakes Res 19(1):175–182CrossRef
  27.Ahlers WW, Reid MR, Kim JP, Hunter KA (1990) Mar Freshw Res 41(6):713–720CrossRef
  28.Nakayama E, Suzuki Y, Fujiwara K, Kitano Y (1989) Anal Sci 5(2):129–139CrossRef
  29.Shotyk W, Krachler M, Chen B (2006) J Environ Monit 8(2):288–292CrossRef
  30.Markert B (2008) Environmental sampling for trace analysis. Wiley, Weinheim
  31.Irrgeher J, Prohaska T, Sturgeon RE, Mester Z, Yang L (2013) Anal Methods 5(7):1687–1694CrossRef
  32.Pallavicini N, Engström E, Baxter DC, Öhlander B, Ingri J, Rodushkin I (2014) In: Journal of Analytical Atomic Spectrometry. J Anal At Spectrom 29(9):1570–1584
  33.Makishima A, Nath BN, Nakamura E (2008) Geochem J 42(3):237–246CrossRef
  34.Field M, Romaniello S, Gordon G, Anbar A (2012) Automated sample preparation for radiogenic and non-traditional metal isotope analysis by MC-ICP-MS. Proceedings of the AGU Fall Meeting. Abstracts p 2823, San Francisco, 3–7 December 2012
  35.Helgoe J, Townsend E, John S (2014) Fe, Zn, and Cd stable isotopes from the eastern tropical South Pacific from GEOTRACES cruise GP16-Methods and data. Proceedings of the AGU Fall Meeting Abstracts p 1263, San Francisco 15–19 December 2014
  36.Oi T, Kawada K, Hosoe M, Kakihana H (1991) Sep Sci Technol 26(10/11):1353–1375CrossRef
  37.Russell W, Papanastassiou D (1978) Anal Chem 50(8):1151–1154CrossRef
  38.Oi T, Ogino H, Hosoe M, Kakihana H (1992) Sep Sci Technol 27(5):631–643CrossRef
  39.Prohaska T (2015) Interferences. In: Sector field mass spectrometry for elemental and isotopic analysis. The Royal Society of Chemistry, Chap. 7 pp 121–125
  40.Horsky M, Irrgeher J, Prohaska T (2015) Anal Bioanal Chem, this volume, submitted
  41.Prohaska T, Irrgeher J, Hanousek O (2015) submitted, Chapter 13: ICP mass spectrometry with sector field analyzer. In: Montaser A (ed) ICP mass spectrometry with sector field analyzer
  42.Coplen TB (2011) Rapid Commun Mass Spectrom 25(17):2538–2560CrossRef
  43.Vanhaecke F, Kyser K (2012) The isotopic composition of the elements. In: Vanhaecke F, Degryse P (eds) Isotopic analysis. Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim, pp 1–29CrossRef
  44.Irrgeher J, Vogl J, Santner J, Prohaska T (2015) Measurement strategies. In: Sector field mass spectrometry for elemental and isotopic analysis. The Royal Society of Chemistry, Chap 8 pp 126–151
  45.Meija J, Yang L, Sturgeon R, Mester Z (2009) Anal Chem 81(16):6774–6778CrossRef
  46.Yang L, Mester Z, Zhou L, Gao S, Sturgeon RE, Meija J (2011) Anal Chem 83(23):8999–9004CrossRef
  47.Newman K (2012) J Anal At Spectrom 27(1):63–70CrossRef
  48.Newman K, Freedman PA, Williams J, Belshaw NS, Halliday AN (2009) J Anal At Spectrom 24(6):742–751CrossRef
  49.Shirai N, Humayun M (2011) J Anal At Spectrom 26(7):1414–1420CrossRef
  50.Buchachenko AL (1995) Chem Rev 95(7):2507–2528CrossRef
  51.Joint Commitee for Guides in Metrology - ISO (2012) Evaluation of measurement data — Guide to the expression of uncertainty in measurement, 3rd edition
  52.Vogl J, Pritzkow W (2012) Reference materials in isotopic analysis. In: Isotopic analysis. Wiley-VCH Verlag GmbH & Co. KGaA, pp 139–163
  53.Vogl J, Pritzkow W (2010) J Anal At Spectrom 25(7):923–932CrossRef
  54.Vogl J, Rosner M, Pritzkow W (2012) Anal Bioanal Chem 1–8
  55.de Laeter JR (2005) Geostand Geoanal Res 29(1):53–61CrossRef
  56.Irrgeher J, Prohaska T (2015) Metrology. In: Sector field mass spectrometry for elemental and isotopic analysis. The Royal Society of Chemistry, Chap. 10 pp 183–196
  57.Brand WA, Coplen TB, Vogl J, Rosner M, Prohaska T (2014) Pure Appl Chem 86(3):425–467CrossRef
  58.Fekiacova Z, Cornu S, Pichat S (2015) Sci Total Environ 517:96–105CrossRef
  59.Shiel AE, Weis D, Orians KJ (2010) Sci Total Environ 408(11):2357–2368CrossRef
  60.Berglund M, Wieser ME (2011) Pure Appl Chem 83(2):397–410CrossRef
  61.Wieser ME, Holden N, Coplen TB, Böhlke JK, Berglund M, Brand WA, De Bièvre P, Gröning M, Loss RD, Meija J (2013) Pure Appl Chem 85(5):1047–1078CrossRef
  62.Hobson KA, Wassenaar LI (2008) Tracking animal migration with stable isotopes, vol 2. Elsevier Science, Oxford, UK
  63.Young ED, Manning CE, Schauble EA, Shahar A, Macris CA, Lazar C, Jordan M (2015) Chem Geol 395:176–195CrossRef
  64.Hoefs J (2008) Stable isotope geochemistry. Springer, Weinheim
  65.Hoefs J (2009) Isotope fractionation processes of selected elements. In: Stable isotope geochemistry. Springer, Berlin, pp 35–92
  66.Faure G, Mensing T (2005) Isotopes: principles and applications, 3rd edn. Wiley, Hoboken
  67.Wiederhold JG (2015) Environ Sci Technol 49(5):2606–2624CrossRef
  68.Fontes JC (1980) Environmental isotopes in groundwater hydrology. In: Fritz P, Fontes JC, (eds) Handbook of environmental isotope geochemistry. Vol. 1. The Netherlands
  69.Peterson BJ, Fry B (1987) Annu Rev Ecol Syst 18:293–320
  70.West JB, Bowen GJ, Cerling TE, Ehleringer JR (2006) Trends Ecol Evol 21(7):408–414CrossRef
  71.Fry B (2007) Stable isotope ecology. Springer
  72.McClelland JW, Valiela I, Michener RH (1997) Limnol Oceanogr 42(5):930–937CrossRef
  73.Wada E, Mizutani H, Minagawa M (1991) Crit Rev Food Sci Nutr 30(4):361–371CrossRef
  74.Middelburg J (2014) Biogeosciences 11(8):2357–2371CrossRef
  75.Burnard PE (ed) (2013) The noble gases as geochemical tracers. Advances in isotope geochemistry. Springer-Verlag, Berlin
  76.Bullen TD (2012) Stable isotopes of transition and post-transition metals as tracers in environmental studies. In: Baskaran M (ed) Handbook of environmental isotope geochemistry. Springer pp 177–203
  77.Weiss DJ, Rehkaemper M, Schoenberg R, McLaughlin M, Kirby J, Campbell PG, Arnold T, Chapman J, Peel K, Gioia S (2008) Environ Sci Technol 42(3):655–664CrossRef
  78.Elburg MA (2012) Geochronological dating. In: Isotopic analysis. Wiley-VCH Verlag GmbH & Co. KGaA, pp 235–274
  79.Jakubowski N, Horsky M, Roos PH, Vanhaecke F, Prohaska T (2015) Inductively coupled plasma mass spectrometry. In: Sector field mass spectrometry for elemental and isotopic analysis. The Royal Society of Chemistry, Chap. 12, pp 208–318
  80.Resano M, Vanhaecke F (2012) Forensic applications. In: Isotopic analysis. Wiley-VCH Verlag GmbH & Co. KGaA, pp 391–418
  81.Degryse P (2012) Archeometric applications. In: Isotopic analysis. Wiley-VCH Verlag GmbH & Co. KGaA, pp 373–390
  82.Kyser K (2012) Isotopes as tracers of elements across the geosphere–biosphere interface. In: Isotopic analysis. Wiley-VCH Verlag GmbH & Co. KGaA, pp 351–372
  83.Wasylenki LE (2012) Establishing the basis for using stable isotope ratios of metals as paleoredox proxies. In: Isotopic analysis. Wiley-VCH Verlag GmbH & Co. KGaA, pp 317–350
  84.Walczyk T (2012) The use of stable isotope techniques for studying mineral and trace element metabolism in humans. In: Isotopic analysis. Wiley-VCH Verlag GmbH & Co. KGaA, pp 435–494
  85.Epov VN, Berail S, Pécheyran C, Amouroux D, Donard OFX (2012) Isotopic analysis via multi-collector inductively coupled plasma mass spectrometry in elemental speciation. In: Isotopic analysis. Wiley-VCH Verlag GmbH & Co. KGaA, pp 495–517
  86.Schauble EA (2013) Proc Natl Acad Sci 110(44):17714–17719CrossRef
  87.Pritzkow W, Wunderli S, Vogl J, Fortunato G (2007) Int J Mass Spectrom 261(1):74–85CrossRef
  88.Rehkämper M, Wombacher F, Horner T, Xue Z (2012) Natural and anthropogenic Cd isotope variations. In: Handbook of environmental isotope geochemistry. Springer, pp 125–154
  89.Lambelet M, Rehkämper M, van de Flierdt T, Xue Z, Kreissig K, Coles B, Porcelli D, Andersson P (2013) Earth Planet Sci Lett 361:64–73CrossRef
  90.Gao B, Liu Y, Sun K, Liang X, Peng PÄ, Sheng G, Fu J (2008) Anal Chim Acta 612(1):114–120CrossRef
  91.Elderfield H, Rickaby R (2000) Nature 405(6784):305–310CrossRef
  92.Cloquet C, Carignan J, Libourel G, Sterckeman T, Perdrix E (2006) Environ Sci Technol 40(8):2525–2530CrossRef
  93.Tanimizu M, Araki Y, Asaoka S, Takahashi Y (2011) Geochem J 45(1):27–32CrossRef
  94.Rouxel O, Ludden J, Fouquet Y (2003) Chem Geol 200(1/2):25–40CrossRef
  95.Lobo L, Degryse P, Shortland A, Vanhaecke F (2013) J Anal At Spectrom 28(8):1213–1219CrossRef
  96.Lobo L, Devulder V, Degryse P, Vanhaecke F (2012) J Anal At Spectrom 27(8):1304–1310CrossRef
  97.Filella M, Belzile N, Chen Y-W (2002) Earth-Sci Rev 59(1):265–285CrossRef
  98.Welle F, Franz R (2011) Food Addit Contam 28(1):115–126CrossRef
  99.Carneado S, Hernández-Nataren E, López-Sánchez JF, Sahuquillo A (2015) Food Chem 166:544–550CrossRef
  100.Tschan M, Robinson BH, Schulin R (2009) Environ Chem 6(2):106–115CrossRef
  101.Nielsen SG, Prytulak J, Halliday AN (2011) Geostand Geoanal Res 35(3):293–306CrossRef
  102.Prytulak J, Nielsen SG, Halliday AN (2011) Geostand Geoanal Res 35(3):307–318CrossRef
  103.Prytulak J, Nielsen S, Ionov D, Halliday A, Harvey J, Kelley K, Niu Y, Peate DW, Shimizu K, Sims K (2013) Earth Planet Sci Lett 365:177–189CrossRef
  104.Ventura GT, Gall L, Siebert C, Prytulak J, Szatmari P, Hürlimann M, Halliday AN (2015) Appl Geochem 59:104–117CrossRef
  105.Gall L, Williams H, Siebert C, Halliday A (2012) J Anal At Spectrom 27(1):137–145CrossRef
  106.Gueguen B, Rouxel O, Ponzevera E, Bekker A, Fouquet Y (2013) Geostand Geoanal Res 37(3):297–317CrossRef
  107.Cameron V, Vance D (2014) Geochim Cosmochim Acta 128:195–211CrossRef
  108.Ratié G, Jouvin D, Garnier J, Rouxel O, Miska S, Guimaraes E, Vieira LC, Sivry Y, Zelano I, Montarges PE (2015) Chem Geol 402:68–76CrossRef
  109.Briche CW, Held A, Berglund M, De Bièvre P, Taylor P (2002) Anal Chim Acta 460(1):41–47CrossRef
  110.Creech J, Baker J, Handler M, Schiller M, Bizzarro M (2013) J Anal At Spectrom 28(6):853–865CrossRef
  111.Lésniewska BA, Godlewska-Zyłkiewicz B, Ruszczynska A, Bulska E, Hulanicki A (2006) Anal Chim Acta 564(2):236–242CrossRef
  112.Vervoort JD, Patchett PJ, Söderlund U, Baker M (2004) Geochem Geophys Geosyst 5(11):Q11002CrossRef
  113.Segal I, Halicz L, Platzner IT (2003) J Anal At Spectrom 18(10):1217–1223CrossRef
  114.Wang J, Ren T, Lu H, Zhou T, Zhou Y (2015) J Anal At Spectrom 30(6):1377–1385CrossRef
  115.Clayton R, Andersson P, Gale NH, Gillis C, Whitehouse MJ (2002) J Anal At Spectrom 17(10):1248–1256CrossRef
  116.Haustein M, Gillis C, Pernicka E (2010) Archaeometry 52(5):816–832CrossRef
  117.Nickel D, Haustein M, Lampke T, Pernicka E (2012) Archaeometry 54(1):167–174CrossRef
  118.Yamazaki E, Nakai S, Sahoo Y, Yokoyama T, Mifune H, Saito T, Chen J, Takagi N, Hokanishi N, Yasuda A (2014) J Archaeol Sci 52:458–467CrossRef
  119.Yamazaki E, Nakai SS, Yokoyama T, Ishihara S, Tang H (2013) Geochem J 47(1):21–35CrossRef
  120.Luo Y, Dabek-Zlotorzynska E, Celo V, Muir DCG, Yang L (2010) Anal Chem 82(9):3922–3928CrossRef
  121.Stewart MA, Spivack AJ (2004) Rev Mineral Geochem 55(1):231–254CrossRef
  122.Fietzke J, Frische M, Hansteen TH, Eisenhauer A (2008) J Anal At Spectrom 23(5):769–772CrossRef
  123.Wiegert C, Mandalakis M, Knowles T, Polymenakou PN, Aeppli C, Macháčková J, Holmstrand H, Evershed RP, Pancost RD, Gustafsson O (2013) Environ Sci Technol 47(12):6449–6456
  124.Elsner M, Jochmann MA, Hofstetter TB, Hunkeler D, Bernstein A, Schmidt TC, Schimmelmann A (2012) Anal Bioanal Chem 403(9):2471–2491CrossRef
  125.Eggenkamp H, Marques J, Graça H (2013) Comunicações Geológicas 100(1):49–53
  126.Gelman F, Halicz L (2010) Int J Mass Spectrom 289(2):167–169CrossRef
  127.Gelman F, Halicz L (2011) Int J Mass Spectrom 307(1):211–213CrossRef
  128.Du Y, Ma T, Yang J, Liu L, Shan H, Cai H, Liu C, Chen L (2013) Int J Mass Spectrom 338:50–56CrossRef
  129.Wei H-Z, Jiang S-Y, Zhu Z-Y, Yang T, Yang J-H, Yan X, Wu H-P, Yang T-L (2015) Talanta 143:302–306CrossRef
  130.de Gois J, Vallelonga P, Spolaor A, Devulder V, Borges DG, Vanhaecke F (2015) Anal Bioanal Chem. doi:10.​1007/​s00216-015-8820-1
  131.Zakon Y, Halicz L, Gelman F (2014) Anal Chem 86(13):6495–6500CrossRef
  132.Eggenkamp H (2014) The geochemistry of stable chlorine and bromine isotopes. Springer
  133.Eggenkamp H (2014) Natural variations of stable chlorine and bromine isotopes on Earth. In: The geochemistry of stable chlorine and bromine isotopes. Advances in isotope geochemistry. Springer: Berlin Heidelberg, pp 115–144
  134.Schilling K, Johnson TM, Mason PRD (2014) Chem Geol 381:125–130CrossRef
  135.Wen H, Carignan J, Chu X, Fan H, Cloquet C, Huang J, Zhang Y, Chang H (2014) Chem Geol 390:164–172CrossRef
  136.von Strandmann PAP, Coath CD, Catling DC, Poulton SW, Elliott T (2014) J Anal At Spectrom 29(9):1648–1659CrossRef
  137.Ellis AS, Johnson TM, Bullen TD (2002) Science 295(5562):2060–2062CrossRef
  138.Johnson TM, Bullen TD (2004) Rev Miner Geochem 55(1):289–317CrossRef
  139.Leng MJ, Sloane HJ (2008) J Quat Sci 23(4):313–319CrossRef
  140.Basile-Doelsch I (2006) J Geochem Explor 88(1/3):252–256CrossRef
  141.Cardinal D, Savoye N, Trull TW, Dehairs F, Kopczynska EE, Fripiat F, Tison J-L, André L (2007) Mar Chem 106(1/2):46–62CrossRef
  142.Misra S, Froelich PN (2012) Science 335(6070):818–823CrossRef
  143.Burton KW, Vigier N (2012) Lithium isotopes as tracers in marine and terrestrial environments. In: Baskaran M (ed) Handbook of environmental isotope geochemistry. Advances in isotope geochemistry. Springer, Berlin, pp 41–59CrossRef
  144.Bowen GJ, West JB (2008) Isotope landscapes for terrestrial migration research. In: Keith AH, Leonard IW (eds) Terrestrial ecology, vol 2. Elsevier, pp 79–105
  145.West JB, Bowen GJ, Dawson TE, Tu KP (eds) (2010) Isoscapes: understanding movement, pattern, and process on earth through isotope mapping. Springer, Weinheim
  146.West JB, Bowen GJ, Dawson TE, Tu KP (2012) J Paleolimnol 47(1):161–162CrossRef
  147.Terzer S, Wassenaar L, Araguás-Araguás L, Aggarwal P (2013) Hydrol Earth Syst Sci 17(11):4713–4728CrossRef
  148.Evans JA, Montgomery J, Wildman G (2009) J Geol Soc 166(4):617–631CrossRef
  149.Evans JA, Montgomery J, Wildman G, Boulton N (2010) J Geol Soc 167(1):1–4CrossRef
  150.Bataille CP, Bowen GJ (2012) Chem Geol 304–305:39–52CrossRef
  151.Brems D, Ganio M, Latruwe K, Balcaen L, Carremans M, Gimeno D, Silvestri A, Vanhaecke F, Muchez P, Degryse P (2013) Archaeometry 55(3):449–464CrossRef
  152.Stürup S, Hansen HR, Gammelgaard B (2008) Anal Bioanal Chem 390(2):541–554CrossRef
  153.Irrgeher J, Zitek A, Cervicek M, Prohaska T (2014) J Anal At Spectrom 29(1):193–200CrossRef
  154.Patriarca M, Lyon T, Fell GS (1997) Am J Clin Nutr 66(3):616–621
  155.Ingle C, Langford N, Harvey L, Dainty JR, Armah C, Fairweather-Tait S, Sharp B, Rose M, Crews H, Lewis J (2002) J Anal At Spectrom 17(11):1502–1505CrossRef
  156.Larner F, Sampson B, Rehkamper M, Weiss DJ, Dainty JR, O'Riordan S, Panetta T, Bain PG (2013) Metallomics 5(2):125–132CrossRef
  157.Urgast DS, Feldmann J (2013) J Anal At Spectrom 28(9):1367–1371CrossRef
  158.Meija J, Yang L, Caruso JA, Mester Z (2006) J Anal At Spectrom 21(11):1294–1297CrossRef
  159.Meija J (2006) Anal Bioanal Chem 385(3):486–499CrossRef
  160.Rodriguez-Castrillón JA, Moldovan M, Ruiz Encinar J, García Alonso JI (2008) J Anal At Spectrom 23(3):318–324CrossRef
  161.Ouerdane L, Mester Z, Meija J (2009) Anal Chem 81(12):5075–5079CrossRef
  162.Zitek A, Irrgeher J, Cervicek M, Horsky M, Kletzl M, Weismann T, Prohaska T (2014) Mar Freshw Res 65(11):978–986CrossRef
  163.Rodriguez-Castrillon J, Moldovan M, Garcia Alonso JI, Lucena JJ, Garcia-Tomas ML, Hernandez-Apaolaza L (2008) Anal Bioanal Chem 390(2):579–590CrossRef
  164.González Iglesias H, Fernández Sánchez ML, García Alonso JI, Sanz-Medel A (2007) Anal Bioanal Chem 389(3):707–713CrossRef
  165.Rodríguez-Castrillón JA, Reyes LH, Marchante-Gayon JM, Moldovan M, García Alonso JI (2008) J Anal At Spectrom 23(4):579–582CrossRef
  166.Huelga-Suarez G, Fernández B, Moldovan M, Alonso JIG (2013) Anal Bioanal Chem 405(9):2901–2909
  167.Huelga-Suarez G, Moldovan M, Garcia-Valiente A, Garcia-Vazquez E, Alonso JIG (2012) Anal Chem 84(1):127–133CrossRef
  168.Urgast DS, Hill S, Kwun IS, Beattie JH, Goenaga-Infante H, Feldmann J (2012) Metallomics 4(10):1057–1063CrossRef
  169.Urgast DS, Ou O, Gordon MJ, Raab A, Nixon GF, Kwun IS, Beattie JH, Feldmann J (2012) Anal Bioanal Chem 402(1):287–297CrossRef
  170.Carames-Pasaron I, Rodríguez-Castrillón JA, Moldovan M, García Alonso JI (2012) Anal Chem 84(1):121–126CrossRef
  171.Rodriguez-Castrillon JA, Moldovan M, Garcia Alonso JI (2009) Anal Bioanal Chem 394(1):351–362CrossRef
  172.Schroder SL, Volk EC, Hagen P (2001) NPAFC Tech Rep 3:9–10
  173.Buckley RM (2001) Trans-generational marking of viviparous fishes to evaluate the efficacy of marine protected areas. Review of Agency Groundfish Research, Assessment, and Management. Washington Department of Fish and Wildlife, Olympia, Washington, Newport, Oregon
  174.Volk EC, Blakley A, Schroder SL, Kuehner SM (2000) Fish Res 46:251–266CrossRef
  175.Kalish JM (1990) Fish Bull 88:657–666
  176.Munro A, Gillanders B, Thurstan S, Crook D, Sanger A (2009) J Fish Biol 75(3):668–684CrossRef
  177.Zitek A, Irrgeher J, Kletzl M, Weismann T, Prohaska T (2013) Fish Manage Ecol 20(4):354–361
  
• 作者单位：Johanna Irrgeher (1) (2)
  Thomas Prohaska (1)
  
  1. Department of Chemistry, Division of Analytical Chemistry, VIRIS Laboratory for Analytical Ecogeochemistry, University of Natural Resources and Life Sciences, Vienna, Konrad-Lorenz-Straße 24, 3430, Tulln, Austria
  2. Department for Marine Bioanalytical Chemistry, Institute for Coastal Research, Helmholtz-Centre for Materials and Coastal Research, Max-Planck-Straße 1, 21502, Geesthacht, Germany
  
• 刊物类别：Chemistry and Materials Science
• 刊物主题：Chemistry
  Analytical Chemistry
  Food Science
  Inorganic Chemistry
  Physical Chemistry
  Monitoring, Environmental Analysis and Environmental Ecotoxicology
  
• 出版者：Springer Berlin / Heidelberg
• ISSN：1618-2650

文摘

Analytical ecogeochemistry is an evolving scientific field dedicated to the development of analytical methods and tools and their application to ecological questions. Traditional stable isotopic systems have been widely explored and have undergone continuous development during the last century. The variations of the isotopic composition of light elements (H, O, N, C, and S) have provided the foundation of stable isotope analysis followed by the analysis of traditional geochemical isotope tracers (e.g., Pb, Sr, Nd, Hf). Questions in a considerable diversity of scientific fields have been addressed, many of which can be assigned to the field of ecogeochemistry. Over the past 15 years, other stable isotopes (e.g., Li, Zn, Cu, Cl) have emerged gradually as novel tools for the investigation of scientific topics that arise in ecosystem research and have enabled novel discoveries and explorations. These systems are often referred to as non-traditional isotopes. The small isotopic differences of interest that are increasingly being addressed for a growing number of isotopic systems represent a challenge to the analytical scientist and push the limits of today’s instruments constantly. This underlines the importance of a metrologically sound concept of analytical protocols and procedures and a solid foundation of data processing strategies and uncertainty considerations before these small isotopic variations can be interpreted in the context of applied ecosystem research. This review focuses on the development of isotope research in ecogeochemistry, the requirements for successful detection of small isotopic shifts, and highlights the most recent and innovative applications in the field.