Inhomogeneous parabolic equations with Hardy potential and memory on the Heisenberg group

Abstract

We study a class of inhomogeneous parabolic equations on the Heisenberg group HN with Hardy-type singular potentials, nonlocal memory terms, and a space-time forcing term: align ∂tu-Hu=λ u\|·\|2H+1(γ)∫0t(t-τ)γ-1|u(τ)|pdτ+tα f in \,HN× (0,T). align Here, γ∈ [0,1), α∈ (-1,∞), p>1, λ>0, and (·)=|∇H\|·\|H|2, where ∇H is the horizontal gradient associated to H. Also, \|·\|H and H denote the Kor\'anyi norm and sub-Laplacian associated with the sub-Riemannian geometry of HN, respectively. The combination of a singular Hardy potential and a memory kernel introduces significant analytical challenges. Using a Harnack-type inequality adapted to the Heisenberg group setting, we obtain quantitative positivity estimates that enable a detailed blow-up analysis. We identify parameter regimes depending on p,γ,α leading to finite-time blow-up or instantaneous blow-up, and establish local well-posedness in the absence of the Hardy potential. These results reveal an interplay between the spatial singularity, temporal nonlocality and a time-dependent forcing term. Finally, under a suitable lower bound on the forcing term f, we derive an explicit lifespan estimate for local-in-time solutions.