Universal corner entanglement from twist operators

Abstract

The entanglement entropy in three-dimensional conformal field theories (CFTs) receives a logarithmic contribution characterized by a regulator-independent function a(θ) when the entangling surface contains a sharp corner with opening angle θ. In the limit of a smooth surface (θ→π), this corner contribution vanishes as a(θ)=σ\,(θ-π)2. In arXiv:1505.04804, we provided evidence for the conjecture that for any d=3 CFT, this corner coefficient σ is determined by CT, the coefficient appearing in the two-point function of the stress tensor. Here, we argue that this is a particular instance of a much more general relation connecting the analogous corner coefficient σn appearing in the nth R\'enyi entropy and the scaling dimension hn of the corresponding twist operator. In particular, we find the simple relation hn/σn=(n-1)π. We show how it reduces to our previous result as n→ 1, and explicitly check its validity for free scalars and fermions. With this new relation, we show that as n→ 0, σn yields the coefficient of the thermal entropy, cS. We also reveal a surprising duality relating the corner coefficients of the scalar and the fermion. Further, we use our result to predict σn for holographic CFTs dual to four-dimensional Einstein gravity. Our findings generalize to other dimensions, and we emphasize the connection to the interval R\'enyi entropies of d=2 CFTs.