带压力的流体动力对准2。多品种

IF 0.9 4区数学 Q3 MATHEMATICS, APPLIED

Quarterly of Applied Mathematics Pub Date : 2022-08-26 DOI:10.1090/qam/1639

J. Lu, E. Tadmor

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引用次数: 1

摘要

本文研究了基于智能体的排列动力学描述所产生的多物种系统的长时间水动力行为。物种之间的相互作用是由一组对称的通信核控制的。我们证明了如果(i)交叉相互作用形成一个重尾连接的核阵列，而(ii)自相互作用由具有奇异头的核控制，则不同物种的群体向平均速度聚集。这里的主要新方面是，对于压力张量的特定形式，在没有闭合假设的情况下，群集行为仍然成立。具体地说，我们证明了多物种连接阵列的长时间群集行为，具有由熵压定律控制的自相互作用(见E. Tadmor [Bull.]。阿米尔。数学。Soc。(2023)，出现])，并由分数pp -对齐驱动。特别地，这样的多物种流体力学接近于单一动力学的描述。这概括了He和Tadmor [Ann]的单动能“无压力”研究。H. poincarcarcarc . Anal。Non linsamaire 38 (2021)， pp. 1031-1053]。

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Hydrodynamic alignment with pressure II. Multi-species

We study the long-time hydrodynamic behavior of systems of multi-species which arise from agent-based description of alignment dynamics. The interaction between species is governed by an array of symmetric communication kernels. We prove that the crowd of different species flocks towards the mean velocity if (i) cross interactions form a heavy-tailed connected array of kernels, while (ii) self-interactions are governed by kernels with singular heads. The main new aspect here is that flocking behavior holds without closure assumption on the specific form of pressure tensors. Specifically, we prove the long-time flocking behavior for connected arrays of multi-species, with self-interactions governed by entropic pressure laws (see E. Tadmor [Bull. Amer. Math. Soc. (2023), to appear]) and driven by fractional p p -alignment. In particular, it follows that such multi-species hydrodynamics approaches a mono-kinetic description. This generalizes the mono-kinetic, “pressure-less” study by He and Tadmor [Ann. Inst. H. Poincaré C Anal. Non Linéaire 38 (2021), pp. 1031–1053].

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来源期刊

Quarterly of Applied Mathematics 数学-应用数学

CiteScore

1.90

自引率

12.50%

发文量

审稿时长

>12 weeks

期刊介绍： The Quarterly of Applied Mathematics contains original papers in applied mathematics which have a close connection with applications. An author index appears in the last issue of each volume. This journal, published quarterly by Brown University with articles electronically published individually before appearing in an issue, is distributed by the American Mathematical Society (AMS). In order to take advantage of some features offered for this journal, users will occasionally be linked to pages on the AMS website.