Legacy effects of multiyear summer drought on soil CO2 production, transport and efflux in a sub-alpine grassland
- Institute of Ecology, University of Innsbruck, Innsbruck, Austria
Climate change is expected to lead to an increase in frequency and severity of extreme climatic events like summer drought. Drought and rewetting have strong impacts on soil respiration, which constitutes the largest flux of CO2 from terrestrial ecosystems to the atmosphere. However, little is known about the role of biotic and abiotic factors in driving CO2 production and transport across the soil profile and how these processes are affected by repeated drought events. Soil CO2 transport can be assessed using the flux-gradient approach, a method which assumes that diffusion is the only transport mechanism for CO2 through soil, with diffusion rates primarily dependent on air-filled pore space. It is therefore generally assumed that the calculated soil CO2 concentration gradient translates directly into soil CO2 efflux, however, a discrepancy between measured soil CO2 efflux and modeled soil CO2 concentration gradients can indicate presence of non-diffusive transport mechanisms.
In a multiyear drought and rewetting experiment at a mountain meadow in the Austrian Alps, we compared soil CO2 production, transport and efflux for plots which were exposed to two and twelve subsequent years of experimental summer drought, respectively, versus plots with ambient precipitation and soil moisture. We measured soil respiration using automated chambers and assessed the production and transport of CO2 using the flux-gradient approach on data obtained with solid-state sensors in three soil depths through the soil profile. We tested the hypothesis that drought-driven reduction in soil respiration will be more intense for the 12-year drought treatment, but the CO2 pulse induced by rewetting will be higher. We furthermore expected that non-diffusive transport mechanisms would play a crucial role during drought and would be more pronounced in the 12-year drought treatment compared to the 2-year drought treatment. Data analysis is currently in progress, the findings will be presented at the conference.
How to cite: Telser, C., Harris, E., Reinthaler, D., and Bahn, M.: Legacy effects of multiyear summer drought on soil CO2 production, transport and efflux in a sub-alpine grassland, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-12366, https://doi.org/10.5194/egusphere-egu21-12366, 2021.
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