High-density hard-core model on Z2 and norm equations in ring Z [[6]-1]

Abstract

We study the Gibbs statistics of high-density hard-core configurations on a unit square lattice Z2, for a general Euclidean exclusion distance D. As a by-product, we solve the disk-packing problem on Z2 for disks of diameter D. The key point is an analysis of solutions to norm equations in Z[[6]-1]. We describe the ground states in terms of M-triangles, i.e., non-obtuse Z2-triangles of a minimal area with the side-lengths ≥ D. There is a finite class (Class S) formed by values D2 generating sliding, a phenomenon leading to countable families of periodic ground states. We identify all D2 with sliding. Each of the remaining classes is proven to be infinite; they are characterized by uniqueness or non-uniqueness of a minimal triangle for a given D2, up to Z2-congruencies. For values of D2 with uniqueness (Class A) we describe the periodic ground states as admissible sub-lattices in Z2 of maximum density. By using the Pirogov-Sinai theory, it allows us to identify the extreme Gibbs measures (pure phases) for large values of fugacity and describe symmetries between them. Next, we analyze the values D2 with non-uniqueness. For some D2 all M-triangles are R2-congruent but not Z2-congruent (Class B0). For other values of D2 there exist non-R2-congruent M-triangles, with different collections of side-lengths (Class B1). Moreover, there are values D2 for which both cases occur (Class B2). The large-fugacity phase diagram for Classes B0, B1, B2 is determined by dominant ground states. Classes A, B0-B2 are described in terms of cosets in Z[[6]-1] by the group of units.