A Schmidt decomposition approach to quantum thermodynamics

TL;DR

This paper introduces a novel, exact formalism based on Schmidt decomposition for analyzing the thermodynamics of arbitrary bipartite quantum systems, including strong coupling regimes, providing a unified and symmetrical framework.

Contribution

It proposes a new approach using Schmidt decomposition to characterize quantum thermodynamics in general autonomous systems, surpassing previous approximative and semi-classical methods.

Findings

Provides a simple, exact framework for quantum energetics.

Enables identification of local effective operators for internal energies.

Ensures energy additivity in the proposed formalism.

Abstract

The development of a self-consistent thermodynamic theory of quantum systems is of fundamental importance for modern physics. Still, despite its essential role in quantum science and technology, there is no unifying formalism for characterizing the thermodynamics within general autonomous quantum systems, and many fundamental open questions remain unanswered. Along these lines, most current efforts and approaches restrict the analysis to particular scenarios of approximative descriptions and semi-classical regimes. Here we propose a novel approach to describe the thermodynamics of arbitrary bipartite autonomous quantum systems based on the well-known Schmidt decomposition. This formalism provides a simple, exact and symmetrical framework for expressing the energetics between interacting systems, including scenarios beyond the standard description regimes, such as strong coupling. We show that this procedure allows a straightforward identification of local effective operators suitable for characterizing the physical local internal energies. We also demonstrate that these quantities naturally satisfy the usual thermodynamic notion of energy additivity.