Convex integration and phenomenologies in turbulence

IF 1.3 Q1 MATHEMATICS EMS Surveys in Mathematical Sciences Pub Date : 2019-01-25 DOI:10.4171/emss/34
T. Buckmaster, V. Vicol
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引用次数: 107

Abstract

In this review article we discuss a number of recent results concerning wild weak solutions of the incompressible Euler and Navier-Stokes equations. These results build on the groundbreaking works of De Lellis and Szekelyhidi Jr., who extended Nash's fundamental ideas on $C^1$ flexible isometric embeddings, into the realm of fluid dynamics. These techniques, which go under the umbrella name convex integration, have fundamental analogies the phenomenological theories of hydrodynamic turbulence. Mathematical problems arising in turbulence (such as the Onsager conjecture) have not only sparked new interest in convex integration, but certain experimentally observed features of turbulent flows (such as intermittency) have also informed new convex integration constructions. First, we give an elementary construction of nonconservative $C^{0+}_{x,t}$ weak solutions of the Euler equations, first proven by De Lellis-Szekelyhidi Jr.. Second, we present Isett's recent resolution of the flexible side of the Onsager conjecture. Here, we in fact follow the joint work of De Lellis-Szekelyhidi Jr. and the authors of this paper, in which weak solutions of the Euler equations in the regularity class $C^{\frac 13-}_{x,t}$ are constructed, attaining any energy profile. Third, we give a concise proof of the authors' recent result, which proves the existence of infinitely many weak solutions of the Navier-Stokes in the regularity class $C^0_t L^{2+}_x \cap C^0_t W^{1,1+}_x$. We conclude the article by mentioning a number of open problems at the intersection of convex integration and hydrodynamic turbulence.
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湍流中的凸积分与现象
在这篇综述文章中,我们讨论了关于不可压缩Euler和Navier-Stokes方程的狂野弱解的一些最新结果。这些结果建立在De Lellis和Szekelyidi Jr.的开创性工作的基础上,他们将纳什关于$C^1$柔性等距嵌入的基本思想扩展到流体动力学领域。这些技术被称为凸积分,与流体动力学湍流的唯象理论有着根本的相似之处。湍流中出现的数学问题(如Onsager猜想)不仅引发了人们对凸积分的新兴趣,而且实验观察到的湍流的某些特征(如间歇性)也为新的凸积分结构提供了信息。首先,我们给出了欧拉方程的非守恒$C^{0+}_{x,t}$弱解的一个初等构造,该解首先由De Lellis Szekelyhidi Jr.证明。在这里,我们实际上遵循了De Lellis Szekelyhidi Jr.和本文作者的联合工作,其中构造了正则性类$C^{\frac 13-}_{x,t}$中欧拉方程的弱解,获得了任何能量分布。第三,我们给出了作者最近的结果的简明证明,该结果证明了正则类$C^0_t L^{2+}_x\cap C^0_tW^{1,1+}_x$中Navier-Stokes的无穷多弱解的存在性。在文章的结尾,我们提到了凸积分和流体动力学湍流交叉点上的一些悬而未决的问题。
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来源期刊
CiteScore
2.30
自引率
0.00%
发文量
4
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