Analysis of fluid velocity vector field divergence ∇·u in function of variable fluid density (x,t)≠ const and conditions for vanishing viscosity of compressible Navier-Stokes equations

Abstract

In this paper, we perform analysis of the fluid velocity vector field divergence ∇ · u derived from the continuity equation, and we explore its application in the Navier-Stokes equations for compressible fluids (x,t) const, occupying all of x∈ R3 space at any t≥ 0. The resulting velocity vector field divergence ∇ · u=-1 (∂ ∂ t +u· ∇ ) is a direct consequence of the fluid density rate of change over time ∂ ∂ t and over space ∇ , in addition to the fluid velocity vector field u(x,t) and the fluid density (x,t) itself. We derive the conditions for the divergence-free fluid velocity vector field ∇ · u=0 in scenarios when the fluid density is not constant (x,t)≠ const over space nor time, and we analyze scenarios of the non-zero divergence ∇ · u 0. We apply the statement for divergence in the Navier-Stokes equation for compressible fluids, and we deduct the condition for vanishing (zero) viscosity term of the compressible Navier-Stokes equation: ∇ (1 (∂ ∂ t +u· ∇ ))=-3 u. In addition to that, we derive even more elementary condition for vanishing viscosity, stating that vanishing viscosity is triggered once scalar function d(x,t)=-1 (∂ ∂ t +u· ∇ ) is harmonic function. Once that condition is satisfied, the viscosity related term of the Navier-Stokes equations for compressible fluids equals to zero, which is known as related to turbulent fluid flows.