An efficient and physically consistent numerical method for the Maxwell–Stefan–Darcy model of two‐phase flow in porous media

Abstract: Numerical modeling of two-phase flow in porous media has extensive applications in subsurface flow and petroleum industry. A comprehensive Maxwell-Stefan-Darcy (MSD) two-phase flow model has been developedrecently, which takes into consideration the friction between two phases by a thermodynamically consistent way. In this article, we for the first time propose an efficient energy stable numerical method for the MSD model, which can preserve multiple important physical properties of the model. First, the propo… Show more

“…EF is originally proposed in Reference 46 and has been successfully applied to the phase-field models 58,59 and two-phase flow in porous media. 42 For S k 𝛼 > 0 and S k+1 𝛼 > 0, using the concavity of ln(S 𝛼 ), we can deduce that…”

“…[5][6][7] To guarantee full mass conservations of both phases, the phase mobilities should be first treated by some discretization strategies, and then total mobility should be obtained through summing the discrete phase mobilities of two phases together. 6,7,41,42 On the basis of the transport property of two-phase flow models, the upwind strategies have been employed as approximations of phase mobilities on the grid-cell boundaries, which can lead to the schemes that ensure the mass conservation law for each phase. 6,7,41,42,[49][50][51] Interestingly but not surprisingly, with the help of upwind mobility strategies, the semi-implicit linear schemes are able to guarantee the positivity of saturations under the Courant-Friedrichs-Lewy (CFL) condition, 6,41,42 while the implicit nonlinear schemes never suffer from this restriction to preserve the positivity.…”

“…6,7,41,42 On the basis of the transport property of two-phase flow models, the upwind strategies have been employed as approximations of phase mobilities on the grid-cell boundaries, which can lead to the schemes that ensure the mass conservation law for each phase. 6,7,41,42,[49][50][51] Interestingly but not surprisingly, with the help of upwind mobility strategies, the semi-implicit linear schemes are able to guarantee the positivity of saturations under the Courant-Friedrichs-Lewy (CFL) condition, 6,41,42 while the implicit nonlinear schemes never suffer from this restriction to preserve the positivity. [49][50][51] In this paper, the fully discrete scheme is constructed combining the locally conservative cell-centered finite difference (CCFD) method with the upwind mobilities.…”

“…Thermodynamically consistent mathematical models, that is, models obeying the second law of thermodynamics, have been increasingly important in many fields, such as phase‐field problems 34‐38 and multicomponent flow with realistic equations of state 32,33,39 . In recent years, thermodynamically consistent models and numerical simulation of incompressible and immiscible two‐phase flows in porous media have been intensively studied in References 22,40‐42. In References 22,40, the two‐phase interfacial free energy and chemical potentials have been introduced to account for capillarity effect, and as a result, the models naturally obey the second law of thermodynamics, but rock compressibility has been never considered.…”

“…Nevertheless, due to the lack of thermodynamically consistent models of two‐phase flows in incompressible or compressible porous media, energy stable methods have been scarcely studied in the past. Very recently, in References 41,42, the energy stable numerical methods were just proposed to approximate the thermodynamically consistent two‐phase flow models established in References 22,40, and meanwhile, an energy stable and mass conservative numerical scheme was proposed for the single‐phase gas flow in porous media with rock compressibility in Reference 43. To our best knowledge, there is no such a scheme developed for two‐phase flow with rock compressibility.…”

An energy stable, conservative and bounds‐preserving numerical method for thermodynamically consistent modeling of incompressible two‐phase flow in porous media with rock compressibility

“…EF is originally proposed in Reference 46 and has been successfully applied to the phase-field models 58,59 and two-phase flow in porous media. 42 For S k 𝛼 > 0 and S k+1 𝛼 > 0, using the concavity of ln(S 𝛼 ), we can deduce that…”

“…[5][6][7] To guarantee full mass conservations of both phases, the phase mobilities should be first treated by some discretization strategies, and then total mobility should be obtained through summing the discrete phase mobilities of two phases together. 6,7,41,42 On the basis of the transport property of two-phase flow models, the upwind strategies have been employed as approximations of phase mobilities on the grid-cell boundaries, which can lead to the schemes that ensure the mass conservation law for each phase. 6,7,41,42,[49][50][51] Interestingly but not surprisingly, with the help of upwind mobility strategies, the semi-implicit linear schemes are able to guarantee the positivity of saturations under the Courant-Friedrichs-Lewy (CFL) condition, 6,41,42 while the implicit nonlinear schemes never suffer from this restriction to preserve the positivity.…”

“…6,7,41,42 On the basis of the transport property of two-phase flow models, the upwind strategies have been employed as approximations of phase mobilities on the grid-cell boundaries, which can lead to the schemes that ensure the mass conservation law for each phase. 6,7,41,42,[49][50][51] Interestingly but not surprisingly, with the help of upwind mobility strategies, the semi-implicit linear schemes are able to guarantee the positivity of saturations under the Courant-Friedrichs-Lewy (CFL) condition, 6,41,42 while the implicit nonlinear schemes never suffer from this restriction to preserve the positivity. [49][50][51] In this paper, the fully discrete scheme is constructed combining the locally conservative cell-centered finite difference (CCFD) method with the upwind mobilities.…”

“…Thermodynamically consistent mathematical models, that is, models obeying the second law of thermodynamics, have been increasingly important in many fields, such as phase‐field problems 34‐38 and multicomponent flow with realistic equations of state 32,33,39 . In recent years, thermodynamically consistent models and numerical simulation of incompressible and immiscible two‐phase flows in porous media have been intensively studied in References 22,40‐42. In References 22,40, the two‐phase interfacial free energy and chemical potentials have been introduced to account for capillarity effect, and as a result, the models naturally obey the second law of thermodynamics, but rock compressibility has been never considered.…”

“…Nevertheless, due to the lack of thermodynamically consistent models of two‐phase flows in incompressible or compressible porous media, energy stable methods have been scarcely studied in the past. Very recently, in References 41,42, the energy stable numerical methods were just proposed to approximate the thermodynamically consistent two‐phase flow models established in References 22,40, and meanwhile, an energy stable and mass conservative numerical scheme was proposed for the single‐phase gas flow in porous media with rock compressibility in Reference 43. To our best knowledge, there is no such a scheme developed for two‐phase flow with rock compressibility.…”

An energy stable, conservative and bounds‐preserving numerical method for thermodynamically consistent modeling of incompressible two‐phase flow in porous media with rock compressibility

Thermodynamically consistent numerical modeling of immiscible two‐phase flow in poro‐viscoelastic media

Discrete energy balance equation via a symplectic second-order method for two-phase flow in porous media