4.7 Article

Iron isotope fingerprints of redox and biogeochemical cycling in the soil-water-rice plant system of a paddy field

Journal

SCIENCE OF THE TOTAL ENVIRONMENT
Volume 574, Issue -, Pages 1622-1632

Publisher

ELSEVIER SCIENCE BV
DOI: 10.1016/j.scitotenv.2016.08.202

Keywords

Tracer; Geochemistry; Dissimilatory iron reduction; Iron uptake; Bangladesh

Funding

  1. CNRS
  2. CNPq
  3. LMI-OCE
  4. 7th European Community Framework Programme (NIDYFICS) [318123]
  5. CNRS-INSU
  6. CUM-AMAZON European Laboratory in Brazil through the INCO-LAB EC [295091]

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The iron isotope composition was used to investigate dissimilatory iron reduction (DIR) processes in an iron-rich waterlogged paddy soil, the iron uptake strategies of plants and its translocation in the different parts of the rice plant along its growth. Fe concentration and isotope composition (delta Fe-56) in irrigation water, precipitates from irrigation water, soil, pore water solution at different depths under the surface water, iron plaque on rice roots, rice roots, stems, leaves and grains were measured. Over the 8.5-10 cm of the vertical profiles investigated, the iron pore water concentration (0.01 to 243 mg center dot 1(-1)) and delta Fe-56 (-0.80 to -3.40%.) varied over a large range. The significant linear co-variation between Ln[Fe] and delta Fe-56 suggests an apparent Rayleigh-type behavior of the DIR processes. An average net fractionation factor between the pore water and the soil substrate of Delta Fe-56 approximate to -1.15 parts per thousand was obtained, taking the average of all the delta Fe-56 values weighted by the, amount of Fe for each sample. These results provide a robust field study confirmation of the conceptual model of Crosby et al. (2005, 2007) for interpreting the iron isotope fractionation observed during DIR, established from a series of laboratories experiments. In addition, the strong enrichment of heavy Fe isotope measured in the root relative to the soil solution suggest that the iron uptake by roots is more likely supplied by iron from plaque and not from the plant-available iron in the pore water. Opposite to what was previously observed for plants following strategy II for iron uptake from soils, an iron isotope fractionation factor of -0.9%. was found from the roots to the rice grains, pointing to isotope fractionation during rice plant growth. All these features highlight the insights iron isotope composition provides into the biogeochemical Fe cycling in the soil-water-rice plant systems studied in nature. (C) 2016 Elsevier B.V. All rights reserved.

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