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Main Authors: Wang, Kaiyuan, Zhang, Yanbing, Li, Qi, Wu, Lei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.03975
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author Wang, Kaiyuan
Zhang, Yanbing
Li, Qi
Wu, Lei
author_facet Wang, Kaiyuan
Zhang, Yanbing
Li, Qi
Wu, Lei
contents Achieving efficient and accurate simulation of the radiative transfer has long been a research challenge. Here we introduce the general synthetic iterative scheme as an easy-to-implement approach to address this issue. First, a macroscopic synthetic equation, which combines the asymptotic equation at the diffusion limit and the "high-order terms" extracted from the transport equation to account for transport effects, is introduced to accelerate the simulation of the radiative transfer equation. Second, the asymptotic preserving property is directly provided by the macroscopic process, eliminating the need for fine spatial discretization in optically thick media, as well as the need for consistency enforcement. Third, to address the issue of opacity discontinuity in the finite volume method, an adaptive least square method for gradient approximation is proposed. Numerical results on several canonical tests demonstrate that, in optically thick problems, our method achieves significant speed-up over the conventional iterative schemes. Finally, with our newly developed method, we reveal the importance of resolving the Knudsen layer in the initial stage of Tophat problem, while in steady-state the Knudsen layer can be under-resolved.
format Preprint
id arxiv_https___arxiv_org_abs_2507_03975
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle General synthetic iterative scheme for multiscale radiative transfer in the finite-volume framework
Wang, Kaiyuan
Zhang, Yanbing
Li, Qi
Wu, Lei
Computational Physics
Achieving efficient and accurate simulation of the radiative transfer has long been a research challenge. Here we introduce the general synthetic iterative scheme as an easy-to-implement approach to address this issue. First, a macroscopic synthetic equation, which combines the asymptotic equation at the diffusion limit and the "high-order terms" extracted from the transport equation to account for transport effects, is introduced to accelerate the simulation of the radiative transfer equation. Second, the asymptotic preserving property is directly provided by the macroscopic process, eliminating the need for fine spatial discretization in optically thick media, as well as the need for consistency enforcement. Third, to address the issue of opacity discontinuity in the finite volume method, an adaptive least square method for gradient approximation is proposed. Numerical results on several canonical tests demonstrate that, in optically thick problems, our method achieves significant speed-up over the conventional iterative schemes. Finally, with our newly developed method, we reveal the importance of resolving the Knudsen layer in the initial stage of Tophat problem, while in steady-state the Knudsen layer can be under-resolved.
title General synthetic iterative scheme for multiscale radiative transfer in the finite-volume framework
topic Computational Physics
url https://arxiv.org/abs/2507.03975