Numerical Solution of Anisotropic Diffusion with Localized Source Using Euler Scheme and Finite Element Method

Numerical Solution of Anisotropic Diffusion with Localized Source Using Euler Scheme and Finite Element Method

This study investigates the numerical modeling of two-dimensional anisotropic diffusion processes involving a spatially localized and temporally limited energy or thermal source. The governing model is formulated as a parabolic partial differential equation, discretized in space using the Finite Ele...

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Bibliographic Details
Main Authors: M. Ziaul Arif, Millatuz Zahroh, Sailah Ar Rizka
Format: Article
Language:Indonesian
Published: Universitas Jember 2025-06-01
Series:Berkala Sainstek
Subjects:
anisotropic diffusion
finite element method
implicit and explicit euler schemes
Online Access:https://bst.jurnal.unej.ac.id/index.php/BST/article/view/53711
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Summary:This study investigates the numerical modeling of two-dimensional anisotropic diffusion processes involving a spatially localized and temporally limited energy or thermal source. The governing model is formulated as a parabolic partial differential equation, discretized in space using the Finite Element Method (FEM) with linear triangular elements, and in time using both explicit and implicit Euler integration schemes. To ensure spatial accuracy, a dense mesh configuration is employed, which has been shown to produce smooth and representative solution distributions. Simulation results demonstrate that the implicit Euler method exhibits superior numerical stability across various time step sizes, whereas the explicit method requires significantly smaller time steps to remain stable. Analysis of the transient regime reveals that the numerical solution gradually converges toward a steady-state configuration once the source is deactivated. These findings confirm that the combination of FEM with implicit time integration and dense meshing is effective in capturing the spatiotemporal dynamics of anisotropic diffusion processes with localized sources, a phenomenon relevant to thermal analysis, anisotropic materials, and environmental modeling.
ISSN:2339-0069

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