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Iron mineral dissolution releases iron and associated organic carbon during permafrost thaw

Author

Listed:
  • Monique S. Patzner

    (University of Tuebingen)

  • Carsten W. Mueller

    (Technical University Muenchen
    University of Copenhagen)

  • Miroslava Malusova

    (University of Tuebingen)

  • Moritz Baur

    (University of Tuebingen)

  • Verena Nikeleit

    (University of Tuebingen)

  • Thomas Scholten

    (University of Tuebingen)

  • Carmen Hoeschen

    (Technical University Muenchen)

  • James M. Byrne

    (University of Tuebingen
    University of Bristol)

  • Thomas Borch

    (Colorado State University)

  • Andreas Kappler

    (University of Tuebingen)

  • Casey Bryce

    (University of Tuebingen
    University of Bristol)

Abstract

It has been shown that reactive soil minerals, specifically iron(III) (oxyhydr)oxides, can trap organic carbon in soils overlying intact permafrost, and may limit carbon mobilization and degradation as it is observed in other environments. However, the use of iron(III)-bearing minerals as terminal electron acceptors in permafrost environments, and thus their stability and capacity to prevent carbon mobilization during permafrost thaw, is poorly understood. We have followed the dynamic interactions between iron and carbon using a space-for-time approach across a thaw gradient in Abisko (Sweden), where wetlands are expanding rapidly due to permafrost thaw. We show through bulk (selective extractions, EXAFS) and nanoscale analysis (correlative SEM and nanoSIMS) that organic carbon is bound to reactive Fe primarily in the transition between organic and mineral horizons in palsa underlain by intact permafrost (41.8 ± 10.8 mg carbon per g soil, 9.9 to 14.8% of total soil organic carbon). During permafrost thaw, water-logging and O2 limitation lead to reducing conditions and an increase in abundance of Fe(III)-reducing bacteria which favor mineral dissolution and drive mobilization of both iron and carbon along the thaw gradient. By providing a terminal electron acceptor, this rusty carbon sink is effectively destroyed along the thaw gradient and cannot prevent carbon release with thaw.

Suggested Citation

  • Monique S. Patzner & Carsten W. Mueller & Miroslava Malusova & Moritz Baur & Verena Nikeleit & Thomas Scholten & Carmen Hoeschen & James M. Byrne & Thomas Borch & Andreas Kappler & Casey Bryce, 2020. "Iron mineral dissolution releases iron and associated organic carbon during permafrost thaw," Nature Communications, Nature, vol. 11(1), pages 1-11, December.
    • Handle: RePEc:nat:natcom:v:11:y:2020:i:1:d:10.1038_s41467-020-20102-6
    DOI: 10.1038/s41467-020-20102-6
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    Cited by:

    1. Jannik Martens & Carsten W. Mueller & Prachi Joshi & Christoph Rosinger & Markus Maisch & Andreas Kappler & Michael Bonkowski & Georg Schwamborn & Lutz Schirrmeister & Janet Rethemeyer, 2023. "Stabilization of mineral-associated organic carbon in Pleistocene permafrost," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    2. Futing Liu & Shuqi Qin & Kai Fang & Leiyi Chen & Yunfeng Peng & Pete Smith & Yuanhe Yang, 2022. "Divergent changes in particulate and mineral-associated organic carbon upon permafrost thaw," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    3. Callesen, I. & Magnussen, A., 2021. "TransparC2U–A two-pool, pedology oriented forest soil carbon simulation model aimed at user investigations of multiple uncertainties," Ecological Modelling, Elsevier, vol. 453(C).
    4. Yunpeng Zhao & Chengzhu Liu & Xingqi Li & Lixiao Ma & Guoqing Zhai & Xiaojuan Feng, 2023. "Sphagnum increases soil’s sequestration capacity of mineral-associated organic carbon via activating metal oxides," Nature Communications, Nature, vol. 14(1), pages 1-11, December.

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