# The Generalized Uncertainty Principle and Higher Dimensions: Linking   Black Holes and Elementary Particles

**Authors:** B. J. Carr

arXiv: 2302.12609 · 2023-02-27

## TL;DR

This paper explores how the Generalized Uncertainty Principle links black holes and elementary particles, especially in higher dimensions, suggesting modifications to the Planck scale and potential implications for TeV-scale quantum gravity.

## Contribution

It introduces models connecting black holes and particles via GUP, extending to higher dimensions, and analyzes how extra dimensions affect the duality and Planck scale.

## Key findings

- Higher dimensions modify black hole and particle size relations.
- Duality between Compton wavelength and Schwarzschild radius can be broken or preserved.
- Extra dimensions can lower the effective Planck mass, enabling TeV-scale quantum gravity.

## Abstract

Black holes play an important role in linking microphysics with macrophysics, with those of the Planck mass ($M_P \sim10^{-5}$g) featuring in any theory of quantum gravity. In particular, the Compton-Schwarzschild correspondence posits a smooth transition between the Compton wavelength ($R_C \propto 1/M$) below the Planck mass and the Schwarzschild radius ($R_{\rm S} \propto M$) above it. The duality between $R_{\rm C}$ and $R_{\rm S}$ implies a form of the Generalized Uncertainty Principle (GUP) and suggests that elementary particles may be sub-Planckian black holes. The simplest possibility is that the ADM mass has the form $M + \beta M_P^2/M$ for some constant $\beta$ and this model can be extended to charged and rotating black holes, clearly relevant to elementary particles. Another possibility is that sub-Planckian black holes may arise in loop quantum gravity and this explicitly links black holes and elementary particles. Higher dimensions may modify both proposals. If there are $n$ extra dimensions, all with the same compactification scale, one expects $R_{\rm S} \propto M^{1/(1+n)}$ below this scale but $R_{\rm C}$ depends on the form of the higher-dimensional wave-function. If it is spherically symmetric, then $R_{\rm C} \propto M^{-1}$, so duality is broken and the Planck mass is reduced, allowing the possibility of TeV quantum gravity. If the wave-function is pancaked in the extra dimensions, $R_{\rm C} \propto M^{-1/(1+n)}$ and so duality is preserved but the Planck mass is unchanged.

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/2302.12609/full.md

## References

42 references — full list in the complete paper: https://tomesphere.com/paper/2302.12609/full.md

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Source: https://tomesphere.com/paper/2302.12609