A universal variational framework for parabolic equations and systems
Abstract
We propose a variational approach to solve Cauchy problems for parabolic equations and systems independently of regularity theory for solutions. This produces a universal and conceptually simple construction of fundamental solution operators (also called propagators) for which we prove off-diagonal estimates, which is new under our assumptions. In the special case of systems for which pointwise local bounds hold for weak solutions, this provides Gaussian upper bound for the corresponding fundamental solution. In particular, we obtain a new proof of Aronson's estimates for real equations. The scheme is general enough to allow systems with higher order elliptic parts on full space or second order elliptic parts on Sobolev spaces with boundary conditions. Another new feature is that the control on lower order coefficients is within critical mixed time-space Lebesgue spaces or even mixed Lorentz spaces.
Cite
@article{arxiv.2211.17000,
title = {A universal variational framework for parabolic equations and systems},
author = {Pascal Auscher and Moritz Egert},
journal= {arXiv preprint arXiv:2211.17000},
year = {2023}
}
Comments
accepted in CVPD. Version sent to editor after modification suggested by the referee and improvement of readability