Integrating Tide‐Driven Wetland Soil Redox and Biogeochemical Interactions Into a Land Surface Model

Sulman, Benjamin N.; Wang, Jiaze; LaFond‐Hudson, Sophie; O’Meara, Theresa A.; Yuan, Fengming; Molins, Sergi; Hammond, Glenn; Forbrich, Inke; Cardon, Zoe G.; Giblin, Anne

doi:10.1029/2023ms004002

J Adv Model Earth Syst

2024

DOI: 10.1029/2023ms004002

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Integrating Tide‐Driven Wetland Soil Redox and Biogeochemical Interactions Into a Land Surface Model

Benjamin N. Sulman,

Jiaze Wang,

Sophie LaFond‐Hudson

et al.

Abstract: Redox processes, aqueous and solid‐phase chemistry, and pH dynamics are key drivers of subsurface biogeochemical cycling and methanogenesis in terrestrial and wetland ecosystems but are typically not included in terrestrial carbon cycle models. These omissions may introduce errors when simulating systems where redox interactions and pH fluctuations are important, such as wetlands where saturation of soils can produce anoxic conditions and coastal systems where sulfate inputs from seawater can influence biogeoc… Show more

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Cited by 4 publications

References 132 publications

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Simulated plant-mediated oxygen input has strong impacts on fine-scale porewater biogeochemistry and weak impacts on integrated methane fluxes in coastal wetlands

Zhou,

O’Meara,

Cardon

et al. 2024

Biogeochemistry

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Methane (CH4) emissions from wetland ecosystems are controlled by redox conditions in the soil, which are currently underrepresented in Earth system models. Plant-mediated radial oxygen loss (ROL) can increase soil O2 availability, affect local redox conditions, and cause heterogeneous distribution of redox-sensitive chemical species at the root scale, which would affect CH4 emissions integrated over larger scales. In this study, we used a subsurface geochemical simulator (PFLOTRAN) to quantify the effects of incorporating either spatially homogeneous ROL or more complex heterogeneous ROL on model predictions of porewater solute concentration depth profiles (dissolved organic carbon, methane, sulfate, sulfide) and column integrated CH4 fluxes for a tidal coastal wetland. From the heterogeneous ROL simulation, we obtained 18% higher column averaged CH4 concentration at the rooting zone but 5% lower total CH4 flux compared to simulations of the homogeneous ROL or without ROL. This difference is because lower CH4 concentrations occurred in the same rhizosphere volume that was directly connected with plant-mediated transport of CH4 from the rooting zone to the atmosphere. Sensitivity analysis indicated that the impacts of heterogeneous ROL on model predictions of porewater oxygen and sulfide concentrations will be more important under conditions of higher ROL fluxes or more heterogeneous root distribution (lower root densities). Despite the small impact on predicted CH4 emissions, the simulated ROL drastically reduced porewater concentrations of sulfide, an effective phytotoxin, indicating that incorporating ROL combined with sulfur cycling into ecosystem models could potentially improve predictions of plant productivity in coastal wetland ecosystems.

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Simulated plant-mediated oxygen input has strong impacts on fine-scale porewater biogeochemistry and weak impacts on integrated methane fluxes in coastal wetlands

Zhou,

O’Meara,

Cardon

et al. 2024

Biogeochemistry

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show abstract

Fluctuations and Benthic Flux of Inorganic Nutrients Associated with Tidal Cycles and Its Implications to the Outwelling Process in Garolim Bay, Yellow Sea

An,

Kim,

Kim

et al. 2024

Ocean Sci. J.

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Short-Term Groundwater Level Fluctuations Drive Subsurface Redox Variability

Machado-Silva,

Weintraub,

Ward

et al. 2024

Environ. Sci. Technol.

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As global change processes modify the extent and functions of terrestrial–aquatic interfaces, the variability of critical and dynamic transitional zones between wetlands and uplands increases. However, it is still unclear how fluctuating water levels at these dynamic boundaries alter groundwater biogeochemical cycling. Here, we used high-temporal resolution data along gradients from wetlands to uplands and during fluctuating water levels at freshwater coastal areas to capture spatiotemporal patterns of groundwater redox potential (E h). We observed that topography influences groundwater E h that is higher in uplands than in wetlands; however, the high variability within TAI zones challenged the establishment of distinct redox zonation. Declining water levels generally decreased E h, but most locations exhibited significant E h variability, which is associated with rare instances of short-term water level fluctuations, introducing oxygen. The E h-oxygen relationship showed distinct hysteresis patterns, reflecting redox poising capacity at higher E h, maintaining more oxidizing states longer than the dissolved oxygen presence. Surprisingly, we observed more frequent oxidizing states in transitional areas and wetlands than in uplands. We infer that occasional oxygen entering specific wetland–upland boundaries acts as critical biogeochemical control points. High-resolution data can capture such rare yet significant biogeochemical instances, supporting redox-informed models and advancing the predictability of climate change feedback.

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Integrating Tide‐Driven Wetland Soil Redox and Biogeochemical Interactions Into a Land Surface Model

Cited by 4 publications

References 132 publications

Simulated plant-mediated oxygen input has strong impacts on fine-scale porewater biogeochemistry and weak impacts on integrated methane fluxes in coastal wetlands

Simulated plant-mediated oxygen input has strong impacts on fine-scale porewater biogeochemistry and weak impacts on integrated methane fluxes in coastal wetlands

Fluctuations and Benthic Flux of Inorganic Nutrients Associated with Tidal Cycles and Its Implications to the Outwelling Process in Garolim Bay, Yellow Sea

Short-Term Groundwater Level Fluctuations Drive Subsurface Redox Variability

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