Thermodynamics as a Consequence of Information Conservation

TL;DR

This paper presents a novel thermodynamics framework based on information conservation, applicable to quantum systems and baths, leading to new insights into heat, work, and engine efficiency without relying on traditional temperature assumptions.

Contribution

It formulates thermodynamics as a consequence of information conservation, extending the theory to quantum systems, arbitrary sizes, and correlations, with a temperature-independent approach.

Findings

Maximum quantum engine efficiency is lower than Carnot's.

Introduces a resource theory framework for temperature-based thermodynamics.

Defines universal laws of thermodynamics from information conservation.

Abstract

Thermodynamics and information have intricate interrelations. Often thermodynamics is considered to be the logical premise to justify that information is physical - through Landauer's principle -, thereby also linking information and thermodynamics. This approach towards information has been instrumental to understand thermodynamics of logical and physical processes, both in the classical and quantum domain. In the present work, we formulate thermodynamics as an exclusive consequence of information conservation. The framework can be applied to the most general situations, beyond the traditional assumptions in thermodynamics: we allow systems and thermal baths to be quantum, of arbitrary sizes and possessing inter-system correlations. Here, systems and baths are not treated differently, rather both are considered on an equal footing. This leads us to introduce a "temperature"-independent formulation of thermodynamics. We rely on the fact that, for a fixed amount of information, measured by the von Neumann entropy, any system can be transformed to a state with the same entropy that possesses minimal energy. This state, known as a completely passive state, acquires Boltzmann-Gibbs canonical form with an intrinsic temperature. We introduce the notions of bound and free energy and use them to quantify heat and work, respectively. Guided by the principle of information conservation, we develop universal notions of equilibrium, heat and work, Landauer's principle and universal fundamental laws of thermodynamics. We demonstrate that the maximum efficiency of a quantum engine with a finite bath is in general lower than that of an ideal Carnot engine. We introduce a resource theoretic framework for our intrinsic temperature based thermodynamics, within which we address the problem of work extraction and state transformations. Finally, the framework is extended to multiple conserved quantities.