Scaling limits of bosonic ground states, from many-body to non-linear Schrödinger

IF 1.3 Q1 MATHEMATICS

EMS Surveys in Mathematical Sciences Pub Date : 2020-02-07 DOI:10.4171/EMSS/40

N. Rougerie

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引用次数: 34

Abstract

How and why may an interacting system of many particles be described assuming that all particles are independent and identically distributed ? This question is at least as old as statistical mechanics itself. Its quantum version has been rejuvenated by the birth of cold atoms physics. In particular the experimental creation of Bose-Einstein condensates directly asks the following variant: why and how can a large assembly of very cold interacting bosons (quantum particles deprived of the Pauli exclusion principle) all populate the same quantum state ? In this text I review the various mathematical techniques allowing to prove that the lowest energy state of a bosonic system forms, in a reasonable macroscopic limit of large particle number, a Bose-Einstein condensate. This means that indeed in the relevant limit all particles approximately behave as if independent and identically distributed, according to a law determined by minimizing a non-linear Schr{o}dinger energy functional. This is a particular instance of the justification of the mean-field approximation in statistical mechanics, starting from the basic many-body Schr{o}dinger Hamiltonian.

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玻色子基态的标度极限，从多体到非线性薛定谔

假设所有粒子都是独立且相同分布的，如何以及为什么可以描述由许多粒子组成的相互作用系统？这个问题至少和统计力学本身一样古老。冷原子物理学的诞生使它的量子版本重新焕发了活力。特别是玻色-爱因斯坦凝聚体的实验创造直接提出了以下变体：为什么以及如何让一个非常冷的相互作用玻色子（被剥夺了泡利排斥原理的量子粒子）的大集合都形成同一个量子态？在本文中，我回顾了各种数学技术，这些技术可以证明玻色子系统的最低能量状态在大粒子数的合理宏观极限下形成玻色-爱因斯坦凝聚体。这意味着，事实上，在相关的极限中，根据通过最小化非线性Schr{o}dinger能量功能。这是统计力学中平均场近似的一个特殊例子，从基本的多体Schr开始{o}dinger哈密顿量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

EMS Surveys in Mathematical Sciences MATHEMATICS-

CiteScore

2.30

自引率

0.00%

发文量