颗粒动力学方程的吹胀与否

IF 2.7 3区数学 Q1 MATHEMATICS, APPLIED

Physica D: Nonlinear Phenomena Pub Date : 2024-10-28 DOI:10.1016/j.physd.2024.134410

José A. Carrillo , Ruiwen Shu , Li Wang , Wuzhe Xu

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引用次数: 0

摘要

对快速粒状介质的简化动力学描述导致了一个带有卷积积分算子的非局部 Vlasov 型方程，其形式与聚集-扩散宏观动力学的连续性方程相同。虽然这些非线性连续性方程的奇异行为在文献中得到了很好的研究，但扩展到相应的粒状动力学方程却非常不容易。主要的问题是，速度方向上形成的奇异性是否会因自由传输导致的相空间剪切而增强或减弱。我们通过细致的数值研究和启发式论证进行了初步研究。我们在数值上开发了一种自适应网格细化的结构保留方法，它能有效捕捉颗粒动力学方程求解中潜在的炸裂行为。我们从分析角度构建了有限时间炸毁的无限质量解，并讨论了该方法如何为有限质量情景提供启示。

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To blow-up or not to blow-up for a granular kinetic equation

A simplified kinetic description of rapid granular media leads to a nonlocal Vlasov-type equation with a convolution integral operator that is of the same form as the continuity equations for aggregation-diffusion macroscopic dynamics. While the singular behavior of these nonlinear continuity equations is well studied in the literature, the extension to the corresponding granular kinetic equation is highly nontrivial. The main question is whether the singularity formed in velocity direction will be enhanced or mitigated by the shear in phase space due to free transport. We present a preliminary study through a meticulous numerical investigation and heuristic arguments. We have numerically developed a structure-preserving method with adaptive mesh refinement that can effectively capture potential blow-up behavior in the solution for granular kinetic equations. We have analytically constructed a finite-time blow-up infinite mass solution and discussed how this can provide insights into the finite mass scenario.

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来源期刊

Physica D: Nonlinear Phenomena 物理-物理：数学物理

CiteScore

7.30

自引率

7.50%

发文量

213

审稿时长

65 days

期刊介绍： Physica D (Nonlinear Phenomena) publishes research and review articles reporting on experimental and theoretical works, techniques and ideas that advance the understanding of nonlinear phenomena. Topics encompass wave motion in physical, chemical and biological systems; physical or biological phenomena governed by nonlinear field equations, including hydrodynamics and turbulence; pattern formation and cooperative phenomena; instability, bifurcations, chaos, and space-time disorder; integrable/Hamiltonian systems; asymptotic analysis and, more generally, mathematical methods for nonlinear systems.