# Thermal quantum spacetime

**Authors:** Isha Kotecha

arXiv: 1907.07497 · 2019-08-13

## TL;DR

This paper proposes a new framework for thermal quantum spacetime by extending equilibrium thermodynamics to background independent quantum gravity systems, emphasizing an information-theoretic approach and its connection to the thermal time hypothesis.

## Contribution

It introduces a background independent extension of thermodynamics, linking entropy to information theory, and applies it to quantum gravity models, providing a statistical foundation for covariant group field theories.

## Key findings

- Generalized Gibbs states suited for background independent settings
- Entropy as a fundamental concept over energy in this framework
- Derivation of covariant group field theories from statistical principles

## Abstract

The intersection of thermodynamics, quantum theory and gravity has revealed many profound insights, all the while posing new puzzles. In this article, we discuss an extension of equilibrium statistical mechanics and thermodynamics potentially compatible with a key feature of general relativity, background independence; and we subsequently use it in a candidate quantum gravity system, thus providing a preliminary formulation of a thermal quantum spacetime. Specifically, we emphasise on an information-theoretic characterisation of generalised Gibbs equilibrium that is shown to be particularly suited to background independent settings, and in which the status of entropy is elevated to being more fundamental than energy. We also shed light on its intimate connections with the thermal time hypothesis. Based on this we outline a framework for statistical mechanics of quantum gravity degrees of freedom of combinatorial and algebraic type, and apply it in several examples. In particular, we provide a quantum statistical basis for the origin of covariant group field theories, shown to arise as effective statistical field theories of the underlying quanta of space in a certain class of generalised Gibbs states.

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## Figures

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## References

58 references — full list in the complete paper: https://tomesphere.com/paper/1907.07497/full.md

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Source: https://tomesphere.com/paper/1907.07497