Mathematical analysis and numerical simulation of the Guyer-Krumhansl heat equation

The Guyer-Krumhansl heat equation has numerous important practical applications in heat conduction problems. In recent years, it turned out that the Guyer-Krumhansl model can effectively describe the thermal behavior of macroscale heterogeneous materials. Thus, the Guyer-Krumhansl equation is a promising candidate to be the next standard model in engineering. However, to support the Guyer-Krumhansl equation's introduction into the engineering practice, its mathematical properties must be thoroughly investigated and understood. In the present paper, we show the basic structure of this particular heat equation, focusing on the differences in comparison to the Fourier heat equation obtained when (tq, mu 2). (0, 0). Additionally, we prove the well-posedness of a particular, practically significant initial and boundary value problem. The stability of the solution is also investigated in the discrete space using a finite difference approach. (c) 2022 Elsevier Inc. All rights reserved.

Automated summary

The Guyer-Krumhansl heat equation has important practical applications in heat conduction problems and can effectively describe the thermal behavior of macroscale heterogeneous materials. It is a promising candidate to be the next standard model in engineering, but its mathematical properties need to be thoroughly investigated and understood. This paper presents the basic structure of the equation and focuses on its differences from the Fourier heat equation. Additionally, it proves the well-posedness of a specific initial and boundary value problem and investigates the stability of the solution using a finite difference approach.