Evolution of Retisol impacted by artificial drainage: What can we learn from stable Fe isotope ratios?
作者: Z. Fekiacova , D. Montagne , A. Duvivier , A. Guihou , P. Deschamps
DOI: 10.1016/J.GEODERMA.2020.114771
关键词:
摘要: Iron oxides are one of the most reactive mineral phases in soils. As a consequence, their transformations can considerably affect dynamics adsorbed elements and associated soil ecosystem services. Understanding Fe soils is therefore key issue for evolution A potentially powerful tool to study Fe-oxides stable isotopes. However, there still important gaps our knowledge isotope fractionations. In order examine fractionations related each process occurring soils, we focused on drainage-influenced sequence Retisols, type characterized by clay translocation subsequent degradation redox processes inducing strong spatial segregation contrasted volumes. We combined isotopic approach at scale bulk horizon different volumes, with mineralogical analyses mass balance calculations investigate consequences drainage fractionation. showed that while were no profile scale, signatures varied significantly among volumes (δ 56 values from − 0.49 ± 0.05 0.29 0.06‰). These variations suggest main mechanisms responsible redistribution particularly accumulation during Mn oxide precipitation makes significant contribution fractionation, these Retisol differentiation. contrast, drainage-induced eluviation does not result further Retisols. The present calculated using iron (goethite, ferrihydrite) have δ close 0‰, minerals enriched heavy isotopes light This provides insight into hydromorphic offers new perspective fractionation
archives-ouvertes.fr
sci-hub.st 参考文章(43)
Ole K. Borggaard, Phase Identification by Selective Dissolution Techniques Iron in Soils and Clay Minerals. pp. 83- 98 ,(1988) , 10.1007/978-94-009-4007-9_5
The Iron Oxides Wiley‐VCH Verlag GmbH. pp. 5- 18 ,(2003) , 10.1002/9783527613229.CH01
T. T. Chao, Liyi Zhou, Extraction Techniques for Selective Dissolution of Amorphous Iron Oxides from Soils and Sediments Soil Science Society of America Journal. ,vol. 47, pp. 225- 232 ,(1983) , 10.2136/SSSAJ1983.03615995004700020010X
George H. Brimhall, Lewis Christopher J., Chris Ford, James Bratt, Gordon Taylor, Oliver Warin, Quantitative geochemical approach to pedogenesis: importance of parent material reduction, volumetric expansion, and eolian influx in lateritization Geoderma. ,vol. 51, pp. 51- 91 ,(1991) , 10.1016/0016-7061(91)90066-3
Alan Matthews, Xiang-Kun Zhu, Keith O’Nions, Kinetic iron stable isotope fractionation between iron (-II) and (-III) complexes in solution Earth and Planetary Science Letters. ,vol. 192, pp. 81- 92 ,(2001) , 10.1016/S0012-821X(01)00432-0
Matthew J. La Force, Scott Fendorf, Solid-phase iron characterization during common selective sequential extractions. Soil Science Society of America Journal. ,vol. 64, pp. 1608- 1615 ,(2000) , 10.2136/SSSAJ2000.6451608X
G.A. Icopini, A.D. Anbar, S.S. Ruebush, M. Tien, S.L. Brantley, Iron isotope fractionation during microbial reduction of iron: The importance of adsorption Geology. ,vol. 32, pp. 205- 208 ,(2004) , 10.1130/G20184.1
M. H. Stolt, C. M. Ogg, J. C. Baker, Strongly Contrasting Redoximorphic Patterns in Virginia Valley and Ridge Paleosols Soil Science Society of America Journal. ,vol. 58, pp. 477- 484 ,(1994) , 10.2136/SSSAJ1994.03615995005800020033X
Stephan Schuth, Julia Hurraß, Carsten Münker, Tim Mansfeldt, Redox-dependent fractionation of iron isotopes in suspensions of a groundwater-influenced soil Chemical Geology. ,vol. 392, pp. 74- 86 ,(2015) , 10.1016/J.CHEMGEO.2014.11.007
A.D. Anbar, Iron stable isotopes: beyond biosignatures Earth and Planetary Science Letters. ,vol. 217, pp. 223- 236 ,(2004) , 10.1016/S0012-821X(03)00572-7