Exact T=0 Partition Functions for Potts Antiferromagnets on Sections of the Simple Cubic Lattice
Abstract
We present exact solutions for the zero-temperature partition function of the q-state Potts antiferromagnet (equivalently, the chromatic polynomial P) on tube sections of the simple cubic lattice of fixed transverse size Lx × Ly and arbitrarily great length Lz, for sizes Lx × Ly = 2 × 3 and 2 × 4 and boundary conditions (a) (FBCx,FBCy,FBCz) and (b) (PBCx,FBCy,FBCz), where FBC (PBC) denote free (periodic) boundary conditions. In the limit of infinite-length, Lz ∞, we calculate the resultant ground state degeneracy per site W (= exponent of the ground-state entropy). Generalizing q from Z+ to C, we determine the analytic structure of W and the related singular locus B which is the continuous accumulation set of zeros of the chromatic polynomial. For the Lz ∞ limit of a given family of lattice sections, W is analytic for real q down to a value qc. We determine the values of qc for the lattice sections considered and address the question of the value of qc for a d-dimensional Cartesian lattice. Analogous results are presented for a tube of arbitrarily great length whose transverse cross section is formed from the complete bipartite graph Km,m.
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