Mode-Wise Spectral Criteria for Coupled Mass Transport in Hybrid PDE--ODE Tumor Microenvironments

Abstract

We study coupled mass transport in a tumor--microenvironment setting with two motile densities (S,R) and non-motile state switching (P,A). The populations diffuse and undergo chemotactic drift; (P,A) follow pointwise ODE switching. A decoupled inhibitory field D satisfies a damped Neumann heat equation, giving maximum-principle bounds and exponential decay. Together with the pointwise invariant P+A, these identities yield global existence, positivity, and long-time reduction to limiting (S,R) kinetics with a unique globally attracting coexistence state. Neumann eigenmode reduction gives closed dispersion relations. The base (S,R) reaction--diffusion block remains stable for all nonconstant modes for any dS,dR>0, excluding classical Turing destabilization. Chemotaxis is posed via a diffusive cue c, since ∇ A is undefined for non-diffusive A. In one-way damped coupling, the linearized mode matrix is block triangular and leaves the (S,R) spectrum unchanged. Two-way coupling adds a feedback rank-one mobility correction, induces effective cross-diffusion, and admits mode growth. We give explicit trace/determinant criteria for unstable Laplacian modes and the resulting instability thresholds.