# Non-singular black holes interiors need physics beyond the standard   model

**Authors:** Ram Brustein, A.J.M. Medved

arXiv: 1902.07990 · 2019-10-23

## TL;DR

This paper argues that understanding black hole interiors requires new physics beyond the standard model and semi-classical gravity, favoring a quantum approach that avoids singularities through exotic matter and quantum effects.

## Contribution

It compares different perspectives on black hole interiors and advocates for a postmodern quantum framework involving exotic matter beyond the standard model.

## Key findings

- Only the postmodern view aligns with current black hole physics.
- Resolving singularities likely requires physics beyond the standard model.
- Quantum effects can stabilize black hole interiors, avoiding singularities.

## Abstract

The composition as well as the very existence of the interior of a Schwarzschild black hole (BH) remains at the forefront of open problems in fundamental physics. To address this issue, we turn to Hawking's "principle of ignorance", which says that, for an observer with limited information, all descriptions that are consistent with known physics are equally valid. We compare three different observers who view the BH from the outside and agree on the external Schwarzschild geometry. First, the modernist, who accepts the classical BH as the final state of gravitational collapse, the singularity theorems that underlie this premise and the central singularity that the theorems predict. The modernist is willing to describe matter in terms of quantum fields in curved space but insists on (semi)classical gravity. Second is the skeptic, who wishes to evade any singular behavior by finding a loophole to the singularity theorems within the realm of classical general relativity (GR). The third is a postmodernist who similarly wants to circumvent the singularity theorems but is willing to invoke exotic quantum physics in the gravitational and/or matter sector to do so. The postmodern view suggests that the uncertainty principle can stabilize a classically singular BH in a similar manner to the stabilization of the classically unstable hydrogen atom: Strong quantum effects in the matter and gravitational sectors resolve the would-be singularity over horizon-sized length scales. The postmodern picture then requires a significant departure from (semi)classical gravity, as well as some exotic matter beyond the standard model of particle physics (SM). We find that only the postmodern framework is consistent with what is known so far about BH physics and conclude that a valid description of the BH interior needs matter beyond the SM and gravitational physics beyond (semi)classical GR.

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1902.07990/full.md

## References

84 references — full list in the complete paper: https://tomesphere.com/paper/1902.07990/full.md

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Source: https://tomesphere.com/paper/1902.07990