English

Numerical solution of the heat conduction problem with memory

Numerical Analysis 2021-11-30 v1 Numerical Analysis Analysis of PDEs

Abstract

It is necessary to use more general models than the classical Fourier heat conduction law to describe small-scale thermal conductivity processes. The effects of heat flow memory and heat capacity memory (internal energy) in solids are considered in first-order integrodifferential evolutionary equations with difference-type kernels. The main difficulties in applying such nonlocal in-time mathematical models are associated with the need to work with a solution throughout the entire history of the process. The paper develops an approach to transforming a nonlocal problem into a computationally simpler local problem for a system of first-order evolution equations. Such a transition is applicable for heat conduction problems with memory if the relaxation functions of the heat flux and heat capacity are represented as a sum of exponentials. The correctness of the auxiliary linear problem is ensured by the obtained estimates of the stability of the solution concerning the initial data and the right-hand side in the corresponding Hilbert spaces. The study's main result is to prove the unconditional stability of the proposed two-level scheme with weights for the evolutionary system of equations for modeling heat conduction in solid media with memory. In this case, finding an approximate solution on a new level in time is not more complicated than the classical heat equation. The numerical solution of a model one-dimensional in space heat conduction problem with memory effects is presented.

Keywords

Cite

@article{arxiv.2111.14090,
  title  = {Numerical solution of the heat conduction problem with memory},
  author = {Petr N. Vabishchevich},
  journal= {arXiv preprint arXiv:2111.14090},
  year   = {2021}
}

Comments

12 pages, 6 figures

R2 v1 2026-06-24T07:54:34.755Z