Optimal existence of weak solutions for the generalised Navier-Stokes-Voigt equations

Abstract

In this study, we investigate the incompressible generalised Navier-Stokes-Voigt equations within a bounded domain ⊂ Rd, where d ≥ 2. The governing momentum equation is expressed as: ∂t(v- v) + ∇ · (v v) + ∇ π - ∇ · ( |D(v)|p-2 D(v) ) = f. Here, for d ∈ \2,3,4\, v represents the velocity field, π denotes the pressure, and f is the external forcing term. The constants and correspond to the relaxation time and kinematic viscosity, respectively. The parameter p ∈ (1, ∞) characterizes the fluid's flow behavior, and D(v) denotes the symmetric part of the velocity gradient ∇ v. For power-law exponents satisfying p>1 when 2≤ d≤ 3, and p> 2dd+2 for d=4, we establish the existence of weak solutions to the generalised Navier-Stokes-Voigt system. Moreover, we prove uniqueness of the weak solution for the same ranges of p. The results are optimal in the sense that p>1 is minimal for 2 ≤ d ≤ 3. Moreover, for p>2dd+2 with d>3, the framework uses a Gelfand triple, allowing the Aubin--Dubinski lemma to yield strong convergence of approximate solutions. This convergence is essential for the existence proof and holds precisely for p>2dd+2 when d=4.