English

Well-posedness and kernel stability for diffusion equations with mixed measure-valued memory

Analysis of PDEs 2026-04-23 v2

Abstract

We investigate a linear diffusion equation incorporating historical effects, characterised by a finite non-negative Borel measure on (0,T](0, \mathfrak T]. This approach accommodates both distributed memory and discrete delays within a unified weak formulation. The measure-valued framework encompasses the memory-free scenario, absolutely continuous kernels, purely atomic delay kernels, and mixed regimes. Our principal result is a finite-time well-posedness theorem for arbitrary finite measures, including kernels with atomic components. More precisely, we prove existence and uniqueness of weak solutions on (τmax,T](-\tau_{\max},\mathfrak T] and derive stability bounds with constants depending explicitly on T\mathfrak T, μ((0,T])\mu((0,\mathfrak T]), and the coercivity and boundedness parameters of the bilinear forms. Subsequently, we demonstrate continuous dependence on the kernel over fixed time intervals, leading to regime-consistency results such as vanishing-memory limits and concentration to a discrete delay. For a restricted dissipative subclass of absolutely continuous kernels, we identify a positive-type condition that results in an energy inequality, and we provide verifiable sufficient criteria, including complete monotonicity, along with an internal-variable representation.

Keywords

Cite

@article{arxiv.2602.19099,
  title  = {Well-posedness and kernel stability for diffusion equations with mixed measure-valued memory},
  author = {Hiroki Ishizaka},
  journal= {arXiv preprint arXiv:2602.19099},
  year   = {2026}
}
R2 v1 2026-07-01T10:46:08.637Z