Kac boundary conditions of the logarithmic minimal models

Abstract

We develop further the implementation and analysis of Kac boundary conditions in the general logarithmic minimal models LM(p,p') with 1 p<p' and p,p' coprime. Working in a strip geometry, we consider the (r,s) boundary conditions, which are organized into infinitely extended Kac tables labeled by r,s=1,2,3,.... They are conjugate to Virasoro Kac representations with conformal dimensions r,s given by the usual Kac formula. On a finite strip of width N, built from a square lattice, the associated integrable boundary conditions are constructed by acting on the vacuum (1,1) boundary with an s-type seam of width s-1 columns and an r-type seam of width -1 columns. The r-type seam contains an arbitrary boundary field . The usual fusion construction of the r-type seam relies on the existence of Wenzl-Jones projectors restricting its application to r<p'. This limitation was recently removed by Pearce, Rasmussen and Villani who further conjectured that the conformal boundary conditions labeled by r are realized, in particular, for =(r)= rp'p. In this paper, we confirm this conjecture by performing extensive numerics on the commuting double row transfer matrices and their associated quantum Hamiltonian chains. Letting [x] denote the fractional part, we fix the boundary field to the specialized values =π2 if [p']=0 and =[ pp']π2 otherwise. For these boundary conditions, we obtain the Kac conformal weights r,s by numerically extrapolating the finite-size corrections to the lowest eigenvalue of the quantum Hamiltonians out to sizes N 32--s. Additionally, by solving local inversion relations, we obtain general analytic expressions for the boundary free energies allowing for more accurate estimates of the conformal data.