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Navier-Stokes-Cahn-Hilliard system in a $3$D perforated domain with free slip and source term: Existence and homogenization

Amartya Chakrabortty, Haradhan Dutta, Hari Shankar Mahato

Abstract

We study a diffuse-interface model for a binary incompressible mixture in a periodically perforated porous medium, described by a time-dependent Navier-Stokes-Cahn-Hilliard (NSCH) system posed on the pore domain $Ω_p^\varepsilon\subset\mathbb{R}^3$. The microscopic model involves a variable viscosity tensor, a non-conservative source term in the Cahn--Hilliard equation, and mixed boundary conditions: no-slip on the outer boundary and Navier slip with zero tangential stress on the surfaces of the solid inclusions. The capillarity strength $λ^\varepsilon>0$ depends on the microscopic scale $\varepsilon>0$. The analysis consists of two main parts. First, for each fixed $\varepsilon>0$, we prove the existence of a weak solution on a finite time interval $(0,T)$ and derive a priori estimates that are uniform with respect to $\varepsilon$ (and $λ^\varepsilon$). Second, we perform the periodic homogenization for the perforated setting, a limit $\varepsilon\to0$. Depending on the limit value $λ$ of the capillarity strength $λ^\varepsilon$, we obtain two distinct effective models: (i) in the vanishing capillarity regime $λ=0$, the limit system is of Stokes-Cahn-Hilliard type, with no macroscopic convection or advection; (ii) in the balanced regime $λ\in(0,+\infty)$, we derive a Navier-Stokes-Cahn-Hilliard system with nonlinear convection and advective transport of the phase field at the macroscopic scale. Finally, we establish the convergence of the microscopic free energy to a homogenized energy functional satisfying an analogous dissipation law.

Navier-Stokes-Cahn-Hilliard system in a $3$D perforated domain with free slip and source term: Existence and homogenization

Abstract

We study a diffuse-interface model for a binary incompressible mixture in a periodically perforated porous medium, described by a time-dependent Navier-Stokes-Cahn-Hilliard (NSCH) system posed on the pore domain . The microscopic model involves a variable viscosity tensor, a non-conservative source term in the Cahn--Hilliard equation, and mixed boundary conditions: no-slip on the outer boundary and Navier slip with zero tangential stress on the surfaces of the solid inclusions. The capillarity strength depends on the microscopic scale . The analysis consists of two main parts. First, for each fixed , we prove the existence of a weak solution on a finite time interval and derive a priori estimates that are uniform with respect to (and ). Second, we perform the periodic homogenization for the perforated setting, a limit . Depending on the limit value of the capillarity strength , we obtain two distinct effective models: (i) in the vanishing capillarity regime , the limit system is of Stokes-Cahn-Hilliard type, with no macroscopic convection or advection; (ii) in the balanced regime , we derive a Navier-Stokes-Cahn-Hilliard system with nonlinear convection and advective transport of the phase field at the macroscopic scale. Finally, we establish the convergence of the microscopic free energy to a homogenized energy functional satisfying an analogous dissipation law.
Paper Structure (20 sections, 26 theorems, 340 equations)

This paper contains 20 sections, 26 theorems, 340 equations.

Key Result

Lemma 4.1

There exists a linear operator such that for every $g\in L^2_0(\Omega_p^\varepsilon)$ the vector field $\phi := \mathcal{B}_p^\varepsilon(g)$ satisfies in the sense of distributions and traces, respectively. Moreover, there exists a constant $C_p>0$, independent of $\varepsilon$, such that

Theorems & Definitions (51)

  • Remark 1
  • Definition 1: Weak solution
  • Lemma 4.1
  • Lemma 4.2
  • proof
  • Lemma 4.3: Restriction operator
  • Lemma 4.4: Extension on primal level
  • proof
  • Lemma 4.5: Extension on the dual level
  • proof
  • ...and 41 more