MR53A-06
Modeling Studies to Constrain Fluid and Gas Migration Associated with Hydraulic Fracturing Operations
Friday, 18 December 2015: 15:15
300 (Moscone South)
Harihar Rajaram1, Daniel Birdsell2, Greg Lackey1, Satish Karra3, Hari Selvi Viswanathan3 and David Dempsey3, (1)University of Colorado at Boulder, Department of Civil, Environmental, and Architectural Engineering, Boulder, CO, United States, (2)University of Colorado at Boulder, Boulder, CO, United States, (3)Los Alamos National Laboratory, Los Alamos, NM, United States
Abstract:
The dramatic increase in the extraction of unconventional oil and gas resources using horizontal wells and hydraulic fracturing (fracking) technologies has raised concerns about potential environmental impacts. Large volumes of hydraulic fracturing fluids are injected during fracking. Incidents of stray gas occurrence in shallow aquifers overlying shale gas reservoirs have been reported; whether these are in any way related to fracking continues to be debated. Computational models serve as useful tools for evaluating potential environmental impacts. We present modeling studies of hydraulic fracturing fluid and gas migration during the various stages of well operation, production, and subsequent plugging. The fluid migration models account for overpressure in the gas reservoir, density contrast between injected fluids and brine, imbibition into partially saturated shale, and well operations. Our results highlight the importance of representing the different stages of well operation consistently. Most importantly, well suction and imbibition both play a significant role in limiting upward migration of injected fluids, even in the presence of permeable connecting pathways. In an overall assessment, our fluid migration simulations suggest very low risk to groundwater aquifers when the vertical separation from a shale gas reservoir is of the order of 1000' or more. Multi-phase models of gas migration were developed to couple flow and transport in compromised wellbores and subsurface formations. These models are useful for evaluating both short-term and long-term scenarios of stray methane release. We present simulation results to evaluate mechanisms controlling stray gas migration, and explore relationships between bradenhead pressures and the likelihood of methane release and transport.