Universal lower bound of the convergence rate of solutions for a semi-linear heat equation with a critical exponent
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Masaki Hoshino
Abstract
We study the behavior of solutions of the Cauchy problem for a semi-linear heat equation with critical non-linearity in the sense of Joseph and Lundgren. It is known that if two solutions are initially close enough near the spatial infinity, then these solutions approach each other. In this paper, we give a universal lower bound of the convergence rate of solutions for a class of initial data. This rate contains a logarithmic term, which is not contained in the super critical non-linearity case. Proofs are given by a comparison method based on matched asymptotic expansion.
Acknowledgements
I would like to thank the anonymous referees for their very careful reading and many valuable suggestions.
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© 2023 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- On a weak maximum principle for a class of fractional diffusive equations
- On a new class of two-variable functional equations on semigroups with involutions
- Universal lower bound of the convergence rate of solutions for a semi-linear heat equation with a critical exponent
- A novel Beta matrix function via Wiman matrix function and their applications
- Error analysis of approximate operators for a particle method based on Voronoi diagram
Artikel in diesem Heft
- Frontmatter
- On a weak maximum principle for a class of fractional diffusive equations
- On a new class of two-variable functional equations on semigroups with involutions
- Universal lower bound of the convergence rate of solutions for a semi-linear heat equation with a critical exponent
- A novel Beta matrix function via Wiman matrix function and their applications
- Error analysis of approximate operators for a particle method based on Voronoi diagram
