• Hyman, Jeffrey Dehaven
• Porter, Mark L.
• Gimenez Martinez, Joaquin
• Chen, Li
• Carey, James William
• Kang, Qinjun
• Lei, Zhou
• Omalley, Daniel
• Frash, Luke
• Rougier, Esteban
• Viswanathan, Hari S.
• Makedonska, Nataliia

Abstract

Despite the impact that hydraulic fracturing has had on the energy sector, the physical mechanisms that control its efficiency and environmental impacts remain poorly understood in part because the length scales involved range from nano-meters to kilo-meters. We characterize flow and transport in shale formations across and between these scales using integrated computational, theoretical, and experimental efforts. At the field scale, we use discrete fracture network modeling to simulate production at a well site whose fracture network is based on a site characterization of a shale formation. At the core scale, we use triaxial fracture experiments and a finite-element discrete-element fracture propagation model with a coupled fluid solver to study dynamic crack propagation in low permeability shale. We use lattice Boltzmann pore-scale simulations and microfluidic experiments in both synthetic and real micromodels to study pore-scale flow phenomenon such as multiphase flow and mixing. A mechanistic description and integration of these multiple scales is required for accurate predictions of production and the eventual optimization of hydrocarbon extraction from unconventional reservoirs.

Topics

• impedance spectroscopy
• pore
• experiment
• simulation
• extraction
• crack
• permeability