指数大偏差估计的“提升”方法及其在非平稳一维点阵安德森模型中的应用

IF 0.5 4区数学 Q3 MATHEMATICS

Journal of Mathematical Physics Analysis Geometry Pub Date : 2023-03-04 DOI:10.1063/5.0150430

O. Hurtado

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引用次数: 0

摘要

对于具有足够规则势分布的随机Schrödinger算子，可以利用Aizenman-Molchanov [common]引入的分数矩方法进行局域性证明。数学。物理学报，157(2)，245-278(1993)]或使用经典Wegner估计作为另一种方法的一部分，例如，Fröhlich-Spencer引入的多尺度分析。数学。物理学，88,151-184(1983)]，由Klein和他的合作者显著发展。当势分布为奇异时，大多数证明关键依赖于与所讨论的算子的有限截断相对应的事件的指数估计;这些估计在某种意义上代替了经典的韦格纳估计。我们引入了一种方法，将对许多平稳模型的估计“提升”到某些密切相关的非平稳模型。作为一种应用，我们使用该方法沿Jitomirskaya-Zhu [comm]开发的非摄动方法在一维晶格上推导出某些非平稳势的安德森定位。数学。物理学报，2016,36(5):1158 - 1158。

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A “lifting” method for exponential large deviation estimates and an application to certain non-stationary 1D lattice Anderson models

Proofs of localization for random Schrödinger operators with sufficiently regular distribution of the potential can take advantage of the fractional moment method introduced by Aizenman–Molchanov [Commun. Math. Phys. 157(2), 245–278 (1993)] or use the classical Wegner estimate as part of another method, e.g., the multi-scale analysis introduced by Fröhlich–Spencer [Commun. Math. Phys. 88, 151–184 (1983)] and significantly developed by Klein and his collaborators. When the potential distribution is singular, most proofs rely crucially on exponential estimates of events corresponding to finite truncations of the operator in question; these estimates in some sense substitute for the classical Wegner estimate. We introduce a method to “lift” such estimates, which have been obtained for many stationary models, to certain closely related non-stationary models. As an application, we use this method to derive Anderson localization on the 1D lattice for certain non-stationary potentials along the lines of the non-perturbative approach developed by Jitomirskaya–Zhu [Commun. Math. Physics 370, 311–324 (2019)] in 2019.

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来源期刊

Journal of Mathematical Physics Analysis Geometry PHYSICS, MATHEMATICAL-

CiteScore

0.70

自引率

20.00%

发文量

审稿时长

>12 weeks

期刊介绍： Journal of Mathematical Physics, Analysis, Geometry (JMPAG) publishes original papers and reviews on the main subjects: mathematical problems of modern physics; complex analysis and its applications; asymptotic problems of differential equations; spectral theory including inverse problems and their applications; geometry in large and differential geometry; functional analysis, theory of representations, and operator algebras including ergodic theory. The Journal aims at a broad readership of actively involved in scientific research and/or teaching at all levels scientists.