Adiabatic driving, geometric phases, and the geometric tensor for classical states

IF 3 3区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY

Annals of Physics Pub Date : 2024-07-04 DOI:10.1016/j.aop.2024.169728

A.D. Bermúdez Manjarres

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引用次数: 0

Abstract

We use the Hilbert space formulation of classical mechanics, known as the Koopman–von Neumann formalism, to study adiabatic driving, geometric phases, and the geometric tensor for classical states. In close relation to what happens to a quantum state, a classical Koopman–von Neumann eigenstate will acquire a geometric phase factor $e x p (i Φ)$ after a closed variation of the parameters $λ$ in its associated Hamiltonian. The explicit form of $Φ$ is then derived for integrable systems, and its relation with the Hannay angle is shown. Additionally, we use quantum formulas to write an adiabatic gauge potential that generates adiabatic unitary flow between classical eigenstates, and we explicitly show the relationship between the potential and the classical geometric phase. We also define a classical analog of the geometric tensor, thus defining a Fubini–Study metric for classical states, and we use the singularities of the tensor to link the transition from Arnold–Liouville integrability to chaos with some of the mathematical formalism of quantum phase transitions. While the formulas and definitions we use originate in quantum mechanics, all the results found are purely classical, no classical or semiclassical limit is ever taken.

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经典态的绝热驱动、几何相位和几何张量

我们使用经典力学的希尔伯特空间表述，即库普曼-冯-诺依曼形式主义，来研究经典状态的绝热驱动、几何相位和几何张量。与量子态的情况密切相关，经典库普曼-冯-诺依曼特征态在其相关哈密顿参数λ发生闭合变化后，将获得几何相位因子 expiΦ。随后，我们推导出了可积分系统中 Φ 的显式，并展示了它与汉内角的关系。此外，我们还利用量子公式写出了一种绝热规势，它能在经典特征状态之间产生绝热单位流，并明确显示了该规势与经典几何相位之间的关系。我们还定义了几何张量的经典类似物，从而定义了经典状态的富比研究度量，并利用张量的奇异性将阿诺德-刘维尔可整性到混沌的过渡与量子相变的一些数学形式联系起来。虽然我们使用的公式和定义源于量子力学，但所有发现的结果都是纯经典的，从未采用经典或半经典极限。

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来源期刊

Annals of Physics 物理-物理：综合

CiteScore

5.30

自引率

3.30%

发文量

211

审稿时长

47 days

期刊介绍： Annals of Physics presents original work in all areas of basic theoretic physics research. Ideas are developed and fully explored, and thorough treatment is given to first principles and ultimate applications. Annals of Physics emphasizes clarity and intelligibility in the articles it publishes, thus making them as accessible as possible. Readers familiar with recent developments in the field are provided with sufficient detail and background to follow the arguments and understand their significance. The Editors of the journal cover all fields of theoretical physics. Articles published in the journal are typically longer than 20 pages.