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Bibliographic Details
Main Authors: Abadias, Luciano, González-Camus, Jorge, Miana, Pedro J., Pozo, Juan C.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2401.16377
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author Abadias, Luciano
González-Camus, Jorge
Miana, Pedro J.
Pozo, Juan C.
author_facet Abadias, Luciano
González-Camus, Jorge
Miana, Pedro J.
Pozo, Juan C.
contents The paper is devoted to understand the large time behaviour and decay of the solution of the discrete heat equation in the one dimensional mesh $\Z$ on $\ell^p$ spaces, and its analogies with the continuous-space case. We do a deep study of the moments of the discrete gaussian kernel (which is given in terms of Bessel functions), in particular the mass conservation principle; that is reflected on the large time behaviour of solutions. We prove asymptotic pointwise and $\ell^p$ decay results for the fundamental solution. We use that estimates to get rates on the $\ell^p$ decay and large time behaviour of solutions. For the $\ell^2$ case, we get optimal decay by use of Fourier techniques.
format Preprint
id arxiv_https___arxiv_org_abs_2401_16377
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Large time behaviour for the heat equation on $\Z,$ moments and decay rates
Abadias, Luciano
González-Camus, Jorge
Miana, Pedro J.
Pozo, Juan C.
Analysis of PDEs
Dynamical Systems
Functional Analysis
35B40, 35A08, 33C10, 39A12
The paper is devoted to understand the large time behaviour and decay of the solution of the discrete heat equation in the one dimensional mesh $\Z$ on $\ell^p$ spaces, and its analogies with the continuous-space case. We do a deep study of the moments of the discrete gaussian kernel (which is given in terms of Bessel functions), in particular the mass conservation principle; that is reflected on the large time behaviour of solutions. We prove asymptotic pointwise and $\ell^p$ decay results for the fundamental solution. We use that estimates to get rates on the $\ell^p$ decay and large time behaviour of solutions. For the $\ell^2$ case, we get optimal decay by use of Fourier techniques.
title Large time behaviour for the heat equation on $\Z,$ moments and decay rates
topic Analysis of PDEs
Dynamical Systems
Functional Analysis
35B40, 35A08, 33C10, 39A12
url https://arxiv.org/abs/2401.16377