Journal
GEOLOGY
Volume 37, Issue 7, Pages 615-618Publisher
GEOLOGICAL SOC AMER, INC
DOI: 10.1130/G25699A.1
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Funding
- UK Natural Environment Research Council Weathering Science Consortium [NE/C004566/1]
- EPSRC [EP/E059678/1] Funding Source: UKRI
- NERC [NE/C521044/1, NE/C521001/1, NE/C004566/1] Funding Source: UKRI
- Engineering and Physical Sciences Research Council [EP/E059678/1] Funding Source: researchfish
- Natural Environment Research Council [NE/C521001/1, NE/C004566/1, NE/C521044/1] Funding Source: researchfish
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Plant-driven fungal weathering is a major pathway of soil formation, yet the precise mechanism by which mycorrhiza alter minerals is poorly understood. Here we report the first direct in situ observations of the effects of a soil fungus on the surface of a mineral over which it grew in a controlled experiment. An ectomycorrhizal fungus was grown in symbiosis with a tree seedling so that individual hyphae expanded across the surface of a biotite flake over a period of three months. Ultramicroscopic and spectroscopic analysis of the fungus-biotite interfaces revealed intimate fungal-mineral attachment, biomechanical forcing, altered interlayer spacings, substantial depletion of potassium (similar to 50 nm depth), oxidation of the biotite Fe(II), and the formation of vermiculite and clusters of Fe(III) oxides. Our study demonstrates the biomechanical-chemical alteration interplay at the fungus-biotite interface at the nanometer scale. Specifically, the weathering process is initiated by physical distortion of the lattice structure of biotite within 1 mu m of the attached fungal hypha. Only subsequently does the distorted volume become chemically altered through dissolution and oxidation reactions that lead to mineral neoformation.
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