Thawing Arctic permafrost can induce hydrologic change and alter redox conditions, shifting the balance of soil organic matter (SOM) decomposition. There remains uncertainty about how soil saturation and redox transitions impact dissolved and gas phase carbon fluxes, and efforts to link hydrobiogeochemical processes to ecosystem-scale models are limited. This study evaluates SOM decomposition of Arctic tundra soils using column experiments, water chemistry measurements, microbial community analysis, and a PFLOTRAN reactive transport model. Soil columns from a thermokarst channel (TC) and an upland tundra (UC) were exposed to cycles of saturation and drainage, which controlled carbon emissions. During saturation, an outflow of dissolved organic carbon from the UC soil correlated with elevated reduced iron and decreased pH; during drainage, UC carbon dioxide fluxes were 70% higher than TC fluxes. Intermittent methane release was observed for TC, consistent with higher methanogen abundance. Slower drainage in the TC soil correlated with more subtle biogeochemical changes. PFLOTRAN simulations captured experimental trends in soil carbon fluxes, oxygen concentrations, and water contents. The model was then used to evaluate additional soil water drainage rates. This study emphasizes the importance of considering hydrologic change when evaluating and simulating SOM decomposition in dynamic Arctic tundra environments.
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| http://dx.doi.org/10.1038/s41598-024-83556-4 | DOI Listing |
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11759714 | PMC |
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Article Synopsis
- Soil organic matter (SOM) is crucial for reducing greenhouse gas emissions and supporting global climate, carbon cycles, and biodiversity.
- Coastal wetland soils, which constitute one-third of SOM, are eroding rapidly due to rising sea levels, highlighting a gap in research on carbon sequestration in these areas compared to upland soils.
- Using solid-state nuclear magnetic resonance (ssNMR), the study reveals that some molecular structures in wetland soils have been preserved for over 1,000 years, but these structures are declining in abundance as decomposition and repolymerization processes occur, making coastal wetland SOM increasingly vulnerable to environmental changes.
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