Conformally invariant boundary conditions in the antiferromagnetic Potts model and the SL(2,R)/U(1) sigma model

Abstract

We initiate a study of the boundary version of the square-lattice Q-state Potts antiferromagnet, with Q ∈ [0,4] real, motivated by the fact that the continuum limit of the corresponding bulk model is a non-compact CFT, closely related with the SL(2,R)k/U(1) Euclidian black-hole coset model. While various types of conformal boundary conditions (discrete and continuous branes) have been formally identified for the the SL(2,R)k/U(1) coset CFT, we are only able in this work to identify conformal boundary conditions (CBC) leading to a discrete boundary spectrum. The conformal boundary conditions (CBC) we find are of two types. The first is free boundary Potts spins, for which we confirm an old conjecture for the generating functions of conformal levels, and show them to be related to characters in a non-linear deformation of the W∞ algebra. The second type of CBC - which corresponds to restricting the values of the Potts spins to a subset of size Q1, or its complement of size Q-Q1, at alternating sites along the boundary - is new, and turns out to be conformal in the antiferromagnetic case only. Using algebraic and numerical techniques, we show that the corresponding spectrum generating functions produce all the characters of discrete representations for the coset CFT. The normalizability bounds of the associated discrete states in the coset CFT are found to have a simple interpretation in terms of boundary phase transitions in the lattice model. For Q = 2 πk, with k 3 integer, we show also how our boundary conditions can be reformulated in terms of a RSOS height model. The spectrum generating functions are then identified with string functions of the compact SU(2)k-2 / U(1) parafermion theory (with symmetry Zk-2). The new alt conditions are needed to cover all the string functions.