# Bounds on CFTs with $W_3$ algebras and AdS$_3$ higher spin theories

**Authors:** Luis Apolo

arXiv: 1705.10402 · 2017-10-12

## TL;DR

This paper establishes bounds on the scaling dimensions and charges of states in 2D CFTs with $W_3$ symmetry, extending universal bounds to theories dual to higher spin AdS$_3$ gravity, under unitarity and modular invariance.

## Contribution

It derives new bounds on conformal weights and $W_3$ charges for CFTs with $W_3$ algebras, linking them to the dual higher spin theories in AdS$_3$.

## Key findings

- Conformal weights of the lightest charged states are bounded by $c/12 + O(1)$.
- States must have $W_3$ charge exceeding a certain threshold related to their conformal weights.
- Results suggest universal constraints on the spectrum of $W_3$-symmetric CFTs in the large central charge limit.

## Abstract

The scaling dimension of the first excited state in two-dimensional conformal field theories (CFTs) satisfies a universal upper bound. Using the modular bootstrap, we extend this result to CFTs with $W_3$ algebras which are generically dual to higher spin theories in AdS$_3$. Assuming unitarity and modular invariance, we show that the conformal weights $h$, $\bar{h}$ of the lightest charged state satisfy $h < c/12 + O(1)$ and $\bar{h} < \bar{c}/12 + O(1)$ in the limit where the central charges $c$, $\bar{c}$ are large. Furthermore, we show that in this limit any consistent CFT with $W_3$ currents must contain at least one state whose $W_3$ charge $w$ obeys $|w| > 4 |h-c/24| /\sqrt{10 \pi c} + O(1)$. We discuss hints on the existence of stronger bounds and comment on the interpretation of our results in the dual higher spin theory.

## Full text

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## Figures

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## References

46 references — full list in the complete paper: https://tomesphere.com/paper/1705.10402/full.md

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Source: https://tomesphere.com/paper/1705.10402