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Understanding soil selenium accumulation and bioavailability through size resolved and elemental characterization of soil extracts

Author

Listed:
  • Julie Tolu

    (Department of Water Resources and Drinking Water (W+T)
    Group of Inorganic Environmental Geochemistry)

  • Sylvain Bouchet

    (Department of Water Resources and Drinking Water (W+T)
    Group of Inorganic Environmental Geochemistry)

  • Julian Helfenstein

    (Group of Plant Nutrition
    Wageningen University)

  • Olivia Hausheer

    (Department of Water Resources and Drinking Water (W+T)
    Group of Inorganic Environmental Geochemistry)

  • Sarah Chékifi

    (Department of Water Resources and Drinking Water (W+T)
    Group of Inorganic Environmental Geochemistry)

  • Emmanuel Frossard

    (Group of Plant Nutrition)

  • Federica Tamburini

    (Group of Plant Nutrition)

  • Oliver A. Chadwick

    (University of California)

  • Lenny H. E. Winkel

    (Department of Water Resources and Drinking Water (W+T)
    Group of Inorganic Environmental Geochemistry)

Abstract

Dietary deficiency of selenium is a global health threat related to low selenium concentrations in crops. Despite the chemical similarity of selenium to the two more abundantly studied elements sulfur and arsenic, the understanding of its accumulation in soils and availability for plants is limited. The lack of understanding of soil selenium cycling is largely due to the unavailability of methods to characterize selenium species in soils, especially the organic ones. Here we develop a size-resolved multi-elemental method using liquid chromatography and elemental mass spectrometry, which enables an advanced characterization of selenium, sulfur, and arsenic species in soil extracts. We apply the analytical approach to soils sampled along the Kohala rainfall gradient on Big Island (Hawaii), which cover a large range of organic carbon and (oxy)hydroxides contents. Similarly to sulfur but contrarily to arsenic, a large fraction of selenium is found associated with organic matter in these soils. However, while sulfur and arsenic are predominantly found as oxyanions in water extracts, selenium mainly exists as small hydrophilic organic compounds. Combining Kohala soil speciation data with concentrations in parent rock and plants further suggests that selenium association with organic matter limits its mobility in soils and availability for plants.

Suggested Citation

  • Julie Tolu & Sylvain Bouchet & Julian Helfenstein & Olivia Hausheer & Sarah Chékifi & Emmanuel Frossard & Federica Tamburini & Oliver A. Chadwick & Lenny H. E. Winkel, 2022. "Understanding soil selenium accumulation and bioavailability through size resolved and elemental characterization of soil extracts," Nature Communications, Nature, vol. 13(1), pages 1-16, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-34731-6
    DOI: 10.1038/s41467-022-34731-6
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    References listed on IDEAS

    as
    1. Julian Helfenstein & Federica Tamburini & Christian von Sperber & Michael S. Massey & Chiara Pistocchi & Oliver A. Chadwick & Peter M. Vitousek & Ruben Kretzschmar & Emmanuel Frossard, 2018. "Combining spectroscopic and isotopic techniques gives a dynamic view of phosphorus cycling in soil," Nature Communications, Nature, vol. 9(1), pages 1-9, December.
    2. D. Gashu & P. C. Nalivata & T. Amede & E. L. Ander & E. H. Bailey & L. Botoman & C. Chagumaira & S. Gameda & S. M. Haefele & K. Hailu & E. J. M. Joy & A. A. Kalimbira & D. B. Kumssa & R. M. Lark & I. , 2021. "The nutritional quality of cereals varies geospatially in Ethiopia and Malawi," Nature, Nature, vol. 594(7861), pages 71-76, June.
    3. T. W. Crowther & K. E. O. Todd-Brown & C. W. Rowe & W. R. Wieder & J. C. Carey & M. B. Machmuller & B. L. Snoek & S. Fang & G. Zhou & S. D. Allison & J. M. Blair & S. D. Bridgham & A. J. Burton & Y. C, 2016. "Quantifying global soil carbon losses in response to warming," Nature, Nature, vol. 540(7631), pages 104-108, December.
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