R\'enyi entanglement entropies in quantum dimer models : from criticality to topological order

Abstract

Thanks to Pfaffian techniques, we study the R\'enyi entanglement entropies and the entanglement spectrum of large subsystems for two-dimensional Rokhsar-Kivelson wave functions constructed from a dimer model on the triangular lattice. By including a fugacity t on some suitable bonds, one interpolates between the triangular lattice (t=1) and the square lattice (t=0). The wave function is known to be a massive Z2 topological liquid for t>0 whereas it is a gapless critical state at t=0. We mainly consider two geometries for the subsystem: that of a semi-infinite cylinder, and the disk-like setup proposed by Kitaev and Preskill [Phys. Rev. Lett. 96, 110404 (2006)]. In the cylinder case, the entropies contain an extensive term -- proportional to the length of the boundary -- and a universal sub-leading constant sn(t). Fitting these cylinder data (up to a perimeter of L=32 sites) provides sn with a very high numerical accuracy (10-9 at t=1 and 10-6 at t=0.5). In the topological Z2 liquid phase we find sn(t>0)=- 2, independent of the fugacity t and the R\'enyi parameter n. At t=0 we recover a previously known result, sn(t=0)=-(1/2)(n)/(n-1) for n<1 and sn(t=0)=-(2)/(n-1) for n>1. In the disk-like geometry -- designed to get rid of the boundary contributions -- we find an entropy s KPn(t>0)=- 2 in the whole massive phase whatever n>0, in agreement with the result of Flammia et al. [Phys. Rev. Lett. 103, 261601 (2009)]. Some results for the gapless limit R KPn(t 0) are discussed.