# Tetrads and q-theory

**Authors:** F.R. Klinkhamer, G.E. Volovik

arXiv: 1812.07046 · 2019-05-10

## TL;DR

This paper introduces a new physical model of the quantum vacuum as a fermionic crystalline medium, uniting general relativity with microscopic fermionic degrees of freedom and enabling the study of topological phases.

## Contribution

It proposes a more physical realization of $q$-theory using a fermionic crystalline vacuum, integrating gravity and microscopic fermionic properties.

## Key findings

- Unites general relativity with fermionic vacuum properties.
- Allows description of topological phases of the quantum vacuum.
- Provides a more realistic model of vacuum degrees of freedom.

## Abstract

As the microscopic structure of the deep relativistic quantum vacuum is unknown, a phenomenological approach ($q$-theory) has been proposed to describe the vacuum degrees of freedom and the dynamics of the vacuum energy after the Big Bang. The original $q$-theory was based on a four-form field strength from a three-form gauge potential. However, this realization of $q$-theory, just as others suggested so far, is rather artificial and does not take into account the fermionic nature of the vacuum. We now propose a more physical realization of the $q$-variable. In this approach, we assume that the vacuum has the properties of a plastic (malleable) fermionic crystalline medium. The new approach unites general relativity and fermionic microscopic (trans-Planckian) degrees of freedom, as the approach involves both the tetrad of standard gravity and the elasticity tetrad of the hypothetical vacuum crystal. This approach also allows for the description of possible topological phases of the quantum vacuum.

## Full text

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## References

19 references — full list in the complete paper: https://tomesphere.com/paper/1812.07046/full.md

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Source: https://tomesphere.com/paper/1812.07046