Abstract
Geological carbon sequestration captures CO2 from industrial sources and stores the CO2 in subsurface reservoirs, a viable strategy for mitigating global climate change. In assessing the environmental impact of the strategy, a key question is how microbial reactions respond to the elevated CO2 concentration. This study uses biogeochemical modeling to explore the influence of CO2 on the thermodynamics and kinetics of common microbial reactions in subsurface environments, including syntrophic oxidation, iron reduction, sulfate reduction, and methanogenesis. The results show that increasing CO2 levels decreases groundwater pH and modulates chemical speciation of weak acids in groundwater, which in turn affect microbial reactions in different ways and to different extents. Specifically, a thermodynamic analysis shows that increasing CO2 partial pressure lowers the energy available from syntrophic oxidation and acetoclastic methanogenesis, but raises the available energy of microbial iron reduction, hydrogenotrophic sulfate reduction and methanogenesis. Kinetic modeling suggests that high CO2 has the potential of inhibiting microbial sulfate reduction while promoting iron reduction. These results are consistent with the observations of previous laboratory and field studies, and highlight the complexity in microbiological responses to elevated CO2 abundance, and the potential power of biogeochemical modeling in evaluating and quantifying these responses.
Highlights
Geological carbon sequestration is a potential strategy for stabilizing atmospheric CO2 levels despite future increases in fossil fuel combustion (IPCC, 2005)
The results show that CO2 significantly impacts the thermodynamics and kinetics of microbial reactions, and can change the outcome of microbial interactions
The above modeling exercises analyzed how the thermodynamics and kinetics of microbial reactions respond to the addition of CO2 into aquifers
Summary
Geological carbon sequestration is a potential strategy for stabilizing atmospheric CO2 levels despite future increases in fossil fuel combustion (IPCC, 2005). This strategy involves carbon capture—capturing CO2 before its emission into the atmosphere—and geological storage— injecting the CO2 into subsurface reservoirs (Benson and Cole, 2008). CO2 or CO2-rich brine from storage reservoirs can diffuse through overlying caprocks, and migrate into aquifers via faults, fractures, and abandoned wells (Keating et al, 2013, 2014). The migration of CO2 into aquifers can lower groundwater pH, increase salinity, dissolve aquifer minerals, and mobilize hazardous solutes, deteriorating the quality of groundwater (Harvey et al, 2013; Humez et al, 2014; Lions et al, 2014; Shao et al, 2015)
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