Logarithmic Minimal Models

TL;DR

This paper constructs and analyzes logarithmic minimal models using integrable lattice models and the Temperley-Lieb algebra, revealing their conformal field theory properties and boundary conditions.

Contribution

It introduces a new class of integrable lattice models for logarithmic minimal models and explores their boundary conditions and representation theory.

Findings

Models yield logarithmic conformal field theories with specific central charges.

Identifies an infinite family of boundary conditions organized in an extended Kac table.

Demonstrates how indecomposable representations arise from fusion processes.

Abstract

Working in the dense loop representation, we use the planar Temperley-Lieb algebra to build integrable lattice models called logarithmic minimal models LM(p,p'). Specifically, we construct Yang-Baxter integrable Temperley-Lieb models on the strip acting on link states and consider their associated Hamiltonian limits. These models and their associated representations of the Temperley-Lieb algebra are inherently non-local and not (time-reversal) symmetric. In the continuum scaling limit, they yield logarithmic conformal field theories with central charges c=1-6(p-p')^2/pp' where p,p'=1,2,... are coprime. The first few members of the principal series LM(m,m+1) are critical dense polymers (m=1, c=-2), critical percolation (m=2, c=0) and logarithmic Ising model (m=3, c=1/2). For the principal series, we find an infinite family of integrable and conformal boundary conditions organized in an extended Kac table with conformal weights Delta_{r,s}=(((m+1)r-ms)^2-1)/4m(m+1), r,s=1,2,.... The associated conformal partition functions are given in terms of Virasoro characters of highest-weight representations. Individually, these characters decompose into a finite number of characters of irreducible representations. We show with examples how indecomposable representations arise from fusion.