3D domino tilings: irregular disks and connected components under flips

Abstract

We consider three-dimensional domino tilings of cylinders RN = D × [0,N] where D ⊂ R2 is a fixed quadriculated disk and N ∈ N. A domino is a 2 × 1 × 1 brick. A flip is a local move in the space of tilings T(RN): remove two adjacent dominoes and place them back after a rotation. The twist is a flip invariant which associates an integer number to each tiling. For some disks D, called regular, two tilings of RN with the same twist can be joined by a sequence of flips once we add vertical space to the cylinder. We have that if D is regular then the size of the largest connected component under flips of T(RN) is (N-12|T(RN)|). The domino group GD captures information of the space of tilings. A disk D is regular if and only if GD is isomorphic to Z Z/(2); sufficiently large rectangles are regular. We prove that certain families of disks are irregular. We show that the existence of a bottleneck in a disk D often implies irregularity. In many, but not all, of these cases, we also prove that D is strongly irregular, i.e., that there exists a surjective homomorphism from GD+ (a subgroup of index two of GD) to the free group of rank two. Moreover, we show that if D is strongly irregular then the cardinality of the largest connected component under flips of T(RN) is O(cN |T(RN)|) for some c ∈ (0,1).