Well-posedness of a generalized Stokes operator on domains with cylindrical ends via layer-potentials

Abstract

We study the generalized Stokes operator equation* V,V0 (arrayccc + V & ∇ \\ ∇* & -V0 array) equation* on a domain with straight cylindrical ends Ω using the method of layer potentials on M ⊃ Ω. The operator 0, 0 is the classical Stokes operator. Under suitable positivity assumptions on V and V0, we prove that is Fredholm. This allows us then to define the single- and double-layer potentials and 12 + . Under further positivity assumptions, we prove that and 12 + are also Fredholm. Under slightly stronger assumptions on V and V0, we prove the invertibility of the operators , , and 12 + . The invertibility of these operators leads to well-posedness results for the associated (linear) Stokes boundary value problem with Dirichlet boundary conditions on Ω. The proofs of these results required us to develop many related tools. In particular, we develop an ``algebra tool kit'' to deal with limit and jump relations of layer potentials. We also develop Green formulas and energy estimates for our generalized Stokes operator on manifolds with straight cylindrical ends, which requires a careful geometric study of the related differential operators, such as the deformation operator . For completeness, we review suitable classes of pseudodifferential operators on manifolds with straight cylindrical ends that were studied in some previous papers of ours (including ``The Stokes operator on manifolds with cylindrical ends,'' J. Diff. Equations, 2024). As an application, we prove the well-posedness result for the Dirichlet problem for the generalized Navier-Stokes system with small data on a domain with cylindrical ends.