A LINDBLADIAN OPERATOR FOR OPEN SYSTEM THERMALIZATION, WITH APPLICATIONS

Q4 Physics and Astronomy

JP Journal of Heat and Mass Transfer Pub Date : 2023-01-23 DOI:10.17654/0973576323008

R. Englman

引用次数: 0

Abstract

A general phenomenological expression is provided, within the frame of the Gorini-Kossakowski-Sudarshan-Lindblad formalism, for the time (t) development of the density operator ρ(t) during thermalization, namely the process such that an open system with arbitrary initial states, when coupled to a thermal bath, ρ (t -> ∞) takes up a Gibbsian form. The theory is applied to a molecular vibrating system, to a semi-classical vibronic entity, and may be applied to the excitation probabilities in a condensed state’s phonon system and to arbitrarily large-scale systems (reaching as far as global warming). A sideline is to an entropy-decreasing Maxwell-demon type quantum state transition. While the prescription may not be unique, it gives rise to an experimentally testable non-monotonicity in the system’s information entropy. The calculated entropy maximum found for an electronic doublet is interpreted as a “transient democratization” of the states and, though lacking a formal proof, a conjecture is proposed for the occurrence of maxima in general instances.

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一个用于开放系统热化的lindbladian算子，及其应用

在gorini - kossakowski - sudarshanan - lindblad形式主义的框架内，提供了密度算子ρ(t)在热化过程中发展的时间(t)的一般现象学表达式，即具有任意初始状态的开放系统，当耦合到热浴时，ρ(t ->∞)呈现吉布斯形式的过程。该理论适用于分子振动系统，半经典振动实体，并可应用于凝聚态声子系统和任意大规模系统(远至全球变暖)的激发概率。副业是熵递减的麦克斯韦妖型量子态跃迁。虽然该处方可能不是唯一的，但它在系统的信息熵中产生了实验可测试的非单调性。计算出的电子重态的熵最大值被解释为状态的“瞬态民主化”，尽管缺乏形式证明，但在一般情况下，对于最大值的出现提出了一个猜想。

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

JP Journal of Heat and Mass Transfer Physics and Astronomy-Atomic and Molecular Physics, and Optics

CiteScore

1.00

自引率

0.00%

发文量

期刊介绍： The JP Journal of Heat and Mass Transfer publishes peer-reviewed articles in heat and mass transfer which enriches basic ideas in this field and provides applicable tools to its users. Articles both theoretical and experimental in nature covering different aspects in the area of heat and mass transfer such as heat transfer in phase change phenomena, machinery and welding operations, porous media and turbulence are considered. Priority is given to those which employ or generate fundamental techniques useful to promote applications in different disciplines of engineering, electronics, communication systems, environmental sciences and climatology. Because a combination of two or more different technologies in a single device may result into a significant development, the journal extends its scope to include papers with the utility value in electronics and communication system. In this spirit, we are devoting certain number of issues to ‘Mechanical Systems and ICT – Convergence’. Survey articles dealing with certain issues in the context of current developments in heat and mass transfer together with their applications in interdisciplinary topics are also entertained.