Richardson Biogeochemistry Lab

Investigating Terrestrial to Marine Biogeochemical Processes

Distribution of Mn Oxidation States in Grassland Soils and Their Relationships with Soil Pores.


Journal article


A. Kravchenko, J. Richardson, Jin Ho Lee, A. Guber
Environmental Science and Technology, 2022

Semantic Scholar DOI PubMed
Cite

Cite

APA   Click to copy
Kravchenko, A., Richardson, J., Lee, J. H., & Guber, A. (2022). Distribution of Mn Oxidation States in Grassland Soils and Their Relationships with Soil Pores. Environmental Science and Technology.


Chicago/Turabian   Click to copy
Kravchenko, A., J. Richardson, Jin Ho Lee, and A. Guber. “Distribution of Mn Oxidation States in Grassland Soils and Their Relationships with Soil Pores.” Environmental Science and Technology (2022).


MLA   Click to copy
Kravchenko, A., et al. “Distribution of Mn Oxidation States in Grassland Soils and Their Relationships with Soil Pores.” Environmental Science and Technology, 2022.


BibTeX   Click to copy

@article{a2022a,
  title = {Distribution of Mn Oxidation States in Grassland Soils and Their Relationships with Soil Pores.},
  year = {2022},
  journal = {Environmental Science and Technology},
  author = {Kravchenko, A. and Richardson, J. and Lee, Jin Ho and Guber, A.}
}

Abstract

Manganese (Mn) is known to be an active contributor to processing and cycling of soil organic carbon (C), yet the exact mechanisms behind its interactions with C are poorly understood. Plant diversity in terrestrial ecosystems drives feedback links between plant C inputs and soil pores, where the latter, in turn, impact the redox environment and Mn. This study examined associations between soil pores (>36 μm Ø) and Mn within intact soils from two grassland ecosystems, after their >6-year implementation in a replicated field experiment. We used μ-XRF imaging and XANES spectroscopy to explore spatial distribution patterns of Mn oxidation states, combined with X-ray computed microtomography and 2D zymography. A high plant diversity system (restored prairie) increased soil C and modified spatial distribution patterns of soil pores as compared to a single species system (monoculture switchgrass). In switchgrass, the abundance of oxidized and reduced Mn oxidation states varied with distance from pores consistently with anticipated O2 diffusion, while in the soil from restored prairie, the spatial patterns suggested that biological activity played a greater role in influencing Mn distributions. Based on the findings, we propose a hypothesis that Mn transformations promote C gains in soils of high plant diversity grasslands.