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Main Authors: Liu, HongZheng, Tian, YiNuo, Wu, Zhiyue
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.06994
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author Liu, HongZheng
Tian, YiNuo
Wu, Zhiyue
author_facet Liu, HongZheng
Tian, YiNuo
Wu, Zhiyue
contents The singularities prevalent in classical thermodynamics largely stem from the "postulate of equal a priori probabilities" neglecting the physical constraints imposed by computational complexity. This paper introduces Complexity Window Thermodynamics (CWT), a framework that characterizes the observer's "ignorance" via a finite complexity budget, thereby naturally smoothing out singular behaviors associated with phase transitions and negative temperatures within this window. We derive a generalized First Law of Thermodynamics driven by a complexity generation potential, which incorporates "information processing work," and demonstrate a universal action-time bound constraining the growth of complexity. CWT not only offers a unified perspective on critical phenomena in condensed matter and the black hole information problem but also suggests that the total generatable complexity of the universe is comparable in order of magnitude to its holographic entropy. Thus, it paves a new pathway for a resource-theoretic unification of thermodynamics, quantum computation, and gravity.
format Preprint
id arxiv_https___arxiv_org_abs_2506_06994
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Heuristic Study of Temperature: Quantum Circuitry in Thermal Systems
Liu, HongZheng
Tian, YiNuo
Wu, Zhiyue
Statistical Mechanics
Quantum Physics
The singularities prevalent in classical thermodynamics largely stem from the "postulate of equal a priori probabilities" neglecting the physical constraints imposed by computational complexity. This paper introduces Complexity Window Thermodynamics (CWT), a framework that characterizes the observer's "ignorance" via a finite complexity budget, thereby naturally smoothing out singular behaviors associated with phase transitions and negative temperatures within this window. We derive a generalized First Law of Thermodynamics driven by a complexity generation potential, which incorporates "information processing work," and demonstrate a universal action-time bound constraining the growth of complexity. CWT not only offers a unified perspective on critical phenomena in condensed matter and the black hole information problem but also suggests that the total generatable complexity of the universe is comparable in order of magnitude to its holographic entropy. Thus, it paves a new pathway for a resource-theoretic unification of thermodynamics, quantum computation, and gravity.
title A Heuristic Study of Temperature: Quantum Circuitry in Thermal Systems
topic Statistical Mechanics
Quantum Physics
url https://arxiv.org/abs/2506.06994