Remediation Potential of Borehole Thermal Energy Storage for Chlorinated Hydrocarbon Plumes: Numerical Modeling in a Variably-Saturated Aquifer

Abstract: Underground thermal energy storage is an efficient technique to boost the share of renewable energies. However, despite being well-established, their environmental impacts such as the interaction with hydrocarbon contaminants is not intensively investigated. This study uses OpenGeoSys software to simulate the heat and mass transport of a borehole thermal energy storage (BTES) system in a shallow unconfined aquifer. A high-temperature (70 C) heat storage scenario was considered which imposes long-term thermal i… Show more

“…The specific response of the microbiome on location to temperature must be investigated; however, most commonly reported temperatures are 20-30 • C with deterioration of the process above 35-40 • C [27][28][29][30][31][32]; thus, thermally enhanced anaerobic dechlorination could be costly, but effective [30]. The highest efficiency of the remediation method will be reflected in the shortening of the time required to reach the target remediation limits through improved biological parameters, e.g., cell growth and (bio)reaction rates [33][34][35] and physical-chemical, e.g., pollutant desorption, their volatilization and (bio)availability [36] and releasing of direct electron donors [35] and thus in lower remediation costs. However, costs could be reduced by replacing conventional heating with some modern and sustainable approach, e.g., geothermal heat pumps and solar heating [37] or synergistic coupling dechlorination remediation with underground thermal energy storage [36,38].…”

“…The highest efficiency of the remediation method will be reflected in the shortening of the time required to reach the target remediation limits through improved biological parameters, e.g., cell growth and (bio)reaction rates [33][34][35] and physical-chemical, e.g., pollutant desorption, their volatilization and (bio)availability [36] and releasing of direct electron donors [35] and thus in lower remediation costs. However, costs could be reduced by replacing conventional heating with some modern and sustainable approach, e.g., geothermal heat pumps and solar heating [37] or synergistic coupling dechlorination remediation with underground thermal energy storage [36,38]. However, in this case, the clogging of the pores caused by Fe 3+ precipitation could also be accompanied by the clogging caused by biomass when additives supporting the decontamination process are added [38].…”

Thermally Enhanced Biodegradation of TCE in Groundwater

“…The specific response of the microbiome on location to temperature must be investigated; however, most commonly reported temperatures are 20-30 • C with deterioration of the process above 35-40 • C [27][28][29][30][31][32]; thus, thermally enhanced anaerobic dechlorination could be costly, but effective [30]. The highest efficiency of the remediation method will be reflected in the shortening of the time required to reach the target remediation limits through improved biological parameters, e.g., cell growth and (bio)reaction rates [33][34][35] and physical-chemical, e.g., pollutant desorption, their volatilization and (bio)availability [36] and releasing of direct electron donors [35] and thus in lower remediation costs. However, costs could be reduced by replacing conventional heating with some modern and sustainable approach, e.g., geothermal heat pumps and solar heating [37] or synergistic coupling dechlorination remediation with underground thermal energy storage [36,38].…”

“…The highest efficiency of the remediation method will be reflected in the shortening of the time required to reach the target remediation limits through improved biological parameters, e.g., cell growth and (bio)reaction rates [33][34][35] and physical-chemical, e.g., pollutant desorption, their volatilization and (bio)availability [36] and releasing of direct electron donors [35] and thus in lower remediation costs. However, costs could be reduced by replacing conventional heating with some modern and sustainable approach, e.g., geothermal heat pumps and solar heating [37] or synergistic coupling dechlorination remediation with underground thermal energy storage [36,38]. However, in this case, the clogging of the pores caused by Fe 3+ precipitation could also be accompanied by the clogging caused by biomass when additives supporting the decontamination process are added [38].…”

Thermally Enhanced Biodegradation of TCE in Groundwater