# Weyl Anomaly and Vacuum Magnetization Current of M5-brane in Background   Flux

**Authors:** Chong-Sun Chu

arXiv: 1903.02817 · 2021-07-28

## TL;DR

This paper explores the relationship between Weyl anomaly and vacuum magnetization currents in M5-brane theories, extending known four-dimensional effects to six dimensions using holography, and predicts a new anomaly contribution for (2,0) superconformal theory.

## Contribution

It generalizes the magnetic Casimir effect and Weyl anomaly connection from 4D to 6D, providing new insights into M5-brane dynamics and anomaly structures via holography.

## Key findings

- Induces a string current in 6D boundary CFT under H-flux.
- Determines gauge contribution to Weyl anomaly in 6D.
- Predicts N^3 scaling of degrees of freedom in (2,0) theory.

## Abstract

It was recently discovered that for a boundary system in the presence of a background magnetic field, the quantum fluctuation of the vacuum would create a non-uniform magnetization density for the vacuum and a magnetization current is induced in the vacuum. It was also shown that this magnetic Casimir effect of the vacuum is closely related to another quantum effect of the vacuum, the Weyl anomaly. Furthermore, the phenomena can be understood in terms of the holography of the boundary system. In this article, we review the derivation of this phenomena from QFT as well as the derivation of it using AdS/BCFT. We then generalize this four dimensional effect to six-dimensions. We use the AdS/BCFT holography to show that in the presence of a 3-form magnetic field strength $H$, a string current is induced in a six-dimensional boundary conformal field theory. This allows us to determine the gauge field contribution to the Weyl anomaly in six-dimensional conformal field theory in a $H$-flux background. For the (2,0) superconformal field theory of $N$ M5-branes, the current has a magnitude proportional to $N^3$ for large $N$. This suggests that the degree of freedoms scales as $N^3$ in the (2,0) superconformal theory of $N$ multiple M5-branes. Our result for the Weyl anomaly is a new prediction for the (2,0) theory.

## Full text

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## Figures

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## References

91 references — full list in the complete paper: https://tomesphere.com/paper/1903.02817/full.md

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Source: https://tomesphere.com/paper/1903.02817