Phase-Textured Complex Viscosity in Linear Viscous Flows: Non-Normality Without Advection, Corner Defects, and 3D Mode Coupling

Abstract

We consider time-harmonic incompressible flow with a spatially resolved complex viscosity field μ*(x,ω) and, at fixed forcing frequency ω>0, its constitutive phase texture (x)=μ*(x,ω). In three-dimensional domains periodic in a spanwise direction z, z-dependence of μ* converts coefficient multiplication into convolution in spanwise Fourier index, yielding an operator-valued Toeplitz/Laurent coupling of modes. Consequently, even spanwise-uniform forcing generically produces ≠ 0 sidebands in the harmonic response as a linear, constitutive effect. We place μ* at the closure level τ=2\,μ*(x,ω)D(v), as the boundary value of the Laplace transform of a causal stress-memory kernel. Under the passivity condition μ*(x,ω) μ>0, the oscillatory Stokes/Oseen operators are realized as m-sectorial operators associated with coercive sectorial forms on bounded Lipschitz (including cornered) domains, yielding existence, uniqueness, and frequency-dependent stability bounds. Spatial variation of renders the viscous operator intrinsically non-normal even in the absence of advection, so amplification is governed by resolvent geometry (and associated pseudospectra), not by eigenvalues alone. In the pure-phase class μ*(x,ω)=μ0(ω)ei(x), the texture strength is quantified by μ0(ω)\|∇\|L∞.