# Universal divergence of the Renyi entropy of a thinly sliced torus at   the Ising fixed point

**Authors:** Bohdan Kulchytskyy, Lauren E. Hayward Sierens, Roger G. Melko

arXiv: 1904.08955 · 2019-07-31

## TL;DR

This paper investigates the universal divergence in the second Renyi entropy of a 2D quantum critical Ising system on a torus when partitioned into a thin slice, revealing fixed point-dependent universal numbers.

## Contribution

It introduces a universal number $oldsymbol{}$ characterizing divergence in entanglement entropy at the Ising fixed point and provides numerical estimates distinguishing it from the Gaussian fixed point.

## Key findings

- _{2,WF} = 0.0174(5) at the Wilson-Fisher fixed point
- _{2,Gaussian} pprox 0.0228
- Universal divergence depends on the fixed point of the quantum critical system.

## Abstract

The entanglement entropy of a quantum critical system can provide new universal numbers that depend on the geometry of the entangling bipartition. We calculate a universal number called $\kappa$, which arises when a quantum critical system is embedded on a two-dimensional torus and bipartitioned into two cylinders. In the limit when one of the cylinders is a thin slice through the torus, $\kappa$ parameterizes a divergence that occurs in the entanglement entropy sub-leading to the area law. Using large-scale Monte Carlo simulations of an Ising model in 2+1 dimensions, we access the second Renyi entropy, and determine that, at the Wilson-Fisher (WF) fixed point, $\kappa_{2,\text{WF}} = 0.0174(5)$. This result is significantly different from its value for the Gaussian fixed point, known to be $\kappa_{2,\text{Gaussian}} \approx 0.0227998$.

## Full text

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## Figures

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## References

47 references — full list in the complete paper: https://tomesphere.com/paper/1904.08955/full.md

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Source: https://tomesphere.com/paper/1904.08955