Impact of mixed boundary conditions and nonsmooth data on layer‐originated nonpremixed combustion problems: Higher‐order convergence analysis

IF 2.6 2区数学 Q1 MATHEMATICS, APPLIED

Studies in Applied Mathematics Pub Date : 2024-09-14 DOI:10.1111/sapm.12763

Shridhar Kumar, Ishwariya R, Pratibhamoy Das

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引用次数: 0

Abstract

This work explores the theoretical and computational impacts of mixed‐type flux conditions and nonsmooth data on boundary/interior layer‐originated singularly perturbed semilinear reaction–diffusion problems. Such problems are prevalent in nonpremixed combustion models and catalytic reaction models. The inclusion of arbitrarily small diffusion terms results in boundary layers influenced by specific flux conditions normalized by perturbation parameters. We have demonstrated theoretically that the sharpness of the boundary layer is significantly reduced when this normalization is independent of the diffusion parameter. In addition, the presence of a nonsmooth source function gives rise to an interior layer in the current problem. We show that using upwind discretizations for mixed boundary fluxes achieves nearly second‐order accuracy if the first derivatives are not normalized concerning perturbation parameters. This outcome arises from the bounds of a prior derivative of the continuous solution. Furthermore, it is theoretically shown that nearly second‐order uniform accuracy can be attained for reaction‐dominated semilinear problems using a hybrid scheme at the discontinuity point. To ensure the uniform stability of the discrete solution, a transformation is necessary for the corresponding discrete problem. Theoretical results are supported by various experiments on nonlinear problems, illustrating the pointwise rates and highlighting both linear and higher‐order accuracy at specific points.

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混合边界条件和非光滑数据对层源非预混合燃烧问题的影响：高阶收敛分析

这项研究探讨了混合型通量条件和非光滑数据对边界/内部层引发的奇异扰动半线性反应扩散问题的理论和计算影响。这类问题普遍存在于非预混合燃烧模型和催化反应模型中。加入任意小的扩散项会导致边界层受到扰动参数归一化的特定通量条件的影响。我们从理论上证明，当这种归一化与扩散参数无关时，边界层的尖锐度会显著降低。此外，在当前问题中，非光滑源函数的存在会产生内部层。我们的研究表明，如果不对一阶导数进行关于扰动参数的归一化处理，使用上风离散法处理混合边界通量几乎可以达到二阶精度。这一结果源于连续解的先导约束。此外，理论上还证明了在不连续点使用混合方案可以使反应主导的半线性问题达到接近二阶的统一精度。为了确保离散解的均匀稳定性，需要对相应的离散问题进行变换。非线性问题的各种实验为理论结果提供了支持，说明了在特定点上的线性和高阶精度的点率和亮点。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Studies in Applied Mathematics 数学-应用数学

CiteScore

4.30

自引率

3.70%

发文量

审稿时长

>12 weeks

期刊介绍： Studies in Applied Mathematics explores the interplay between mathematics and the applied disciplines. It publishes papers that advance the understanding of physical processes, or develop new mathematical techniques applicable to physical and real-world problems. Its main themes include (but are not limited to) nonlinear phenomena, mathematical modeling, integrable systems, asymptotic analysis, inverse problems, numerical analysis, dynamical systems, scientific computing and applications to areas such as fluid mechanics, mathematical biology, and optics.