库仑气体的过度拥挤和分离估计

IF 3.1 1区 数学 Q1 MATHEMATICS
Eric Thoma
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引用次数: 0

摘要

我们证明了基于牛顿定理的各向同性平均输运方法对任意维度d≥2$d \ge 2$的库仑气体的几个结果。首先,我们证明了高密度jancovicii - lebowitz - manificat定律,扩展了Armstrong和Serfaty的微观密度界,并建立了2维电荷过量的严格亚高斯尾。证明了液滴边缘存在微观极限点过程。接下来,我们证明了合并点的k点相关函数的最优上界,包括k=1$k=1$时库仑气体的Wegner估计。我们证明了适当重新标度的第k个最小粒子间隙的紧密性,识别了d=2$d=2$和d≥3$d \ ge3 $的三项展开的正确顺序,以及上下尾估计。特别地,我们将Ameur和Romero确定的二维“完美冻结状态”扩展到更高的维度。最后,我们给出了液滴边界附近目前最先进的正电荷差异边界,并证明了分数量子霍尔效应中劳克林态的不可压缩性,从大微观尺度开始。利用光滑线性统计波动的刚性,我们展示了如何将正差异界提升为对特定区域的绝对差异的估计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Overcrowding and separation estimates for the Coulomb gas

We prove several results for the Coulomb gas in any dimension d 2 $d \ge 2$ that follow from isotropic averaging, a transport method based on Newton's theorem. First, we prove a high-density Jancovici–Lebowitz–Manificat law, extending the microscopic density bounds of Armstrong and Serfaty and establishing strictly sub-Gaussian tails for charge excess in dimension 2. The existence of microscopic limiting point processes is proved at the edge of the droplet. Next, we prove optimal upper bounds on the k $k$ -point correlation function for merging points, including a Wegner estimate for the Coulomb gas for k = 1 $k=1$ . We prove the tightness of the properly rescaled k $k$ th minimal particle gap, identifying the correct order in d = 2 $d=2$ and a three term expansion in d 3 $d \ge 3$ , as well as upper and lower tail estimates. In particular, we extend the two-dimensional “perfect-freezing regime” identified by Ameur and Romero to higher dimensions. Finally, we give positive charge discrepancy bounds which are state of the art near the droplet boundary and prove incompressibility of Laughlin states in the fractional quantum Hall effect, starting at large microscopic scales. Using rigidity for fluctuations of smooth linear statistics, we show how to upgrade positive discrepancy bounds to estimates on the absolute discrepancy in certain regions.

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来源期刊
CiteScore
6.70
自引率
3.30%
发文量
59
审稿时长
>12 weeks
期刊介绍: Communications on Pure and Applied Mathematics (ISSN 0010-3640) is published monthly, one volume per year, by John Wiley & Sons, Inc. © 2019. The journal primarily publishes papers originating at or solicited by the Courant Institute of Mathematical Sciences. It features recent developments in applied mathematics, mathematical physics, and mathematical analysis. The topics include partial differential equations, computer science, and applied mathematics. CPAM is devoted to mathematical contributions to the sciences; both theoretical and applied papers, of original or expository type, are included.
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