Asymptotically self-similar global solutions for Hardy-Hénon parabolic equations (2503.12408v1)

Abstract: We construct asymptotically self-similar global solutions to the Hardy-H\'enon parabolic equation $\partial_t u - \Delta u = \pm |x|^{\gamma} |u|^{\alpha-1} u$, $\alpha>1$, $\gamma \in \mathbb{R}$ for a large class of initial data belonging to weighted Lorentz spaces. The solution may be asymptotic to a self-similar solution of the linear heat equation or to a self-similar solution to the Hardy-H\'enon parabolic equation depending on the speed of decay of the initial data at infinity. The asymptotic results are new for the H\'enon case $\gamma>0$. We also prove the stability of the asymptotic profiles. Our approach applies for $\gamma> -\min(2,d)$ and unifies the cases $\gamma>0$, $\gamma=0$ and $-\min(2,d)<\gamma<0$. For complex-valued initial data, a more intricate asymptotic behaviors can be shown; if either one of the real part or the imaginary part of the initial data has a faster spatial decay, then the solution exhibits a combined Nonlinear-"Modified Linear" asymptotic behavior, which is completely new even for the Fujita case $\gamma=0$. In Appendix, we show the non-existence of local positive solutions for supercritical initial data.