Bilayer Coulomb phase of two dimensional dimer models: Absence of power-law columnar order

Abstract

We study the fully-packed dimer model on the bilayer square lattice with fugacity equal to z (1) for inter-layer (intra-layer) dimers, and intra-layer interaction V between neighbouring parallel dimers on any elementary plaquette in either layer. For a range of not-too-large z> 0 and repulsive interactions 0< V < Vs (with Vs ≈ 2.1), we demonstrate the existence of a bilayer Coulomb phase with purely dipolar two-point functions, i.e., without the power-law columnar order that characterizes the usual Coulomb phase of square and honeycomb lattice dimer models. The transition line zc(V) separating this bilayer Coulomb phase from a large-z disordered phase is argued to be in the inverted Kosterlitz-Thouless universality class. Additionally, we argue for the possibility of a tricritical point at which the bilayer Coulomb phase, the large-z disordered phase and the large-V staggered phase meet in the large-z, large-V part of the phase diagram. In contrast, for the attractive case with Vcb < V ≤ 0 (Vcb ≈ -1.2), we argue that any z > 0 destroys the power-law correlations of the z=0 decoupled layers, and leads immediately to a short-range correlated state, albeit with a slow crossover for small |V|. For Vc < V < Vcb (Vc ≈ -1.55), we predict that any small nonzero z immediately gives rise to long-range bilayer columnar order although the z=0 decoupled layers remain power-law correlated in this regime; this implies a non-monotonic z dependence of the columnar order parameter for fixed V in this regime. This bilayer columnar ordered state is separated from the large-z disordered state by a line of Ashkin-Teller transitions z AT(V).