Hyperplanes of Squier's cube complexes

Abstract

To any semigroup presentation P= R and base word w ∈ + may be associated a nonpositively curved cube complex S(P,w), called a Squier complex, whose underlying graph consists of the words of + equal to w modulo P where two such words are linked by an edge when one can be transformed into the other by applying a relation of R. A group is a diagram group if it is the fundamental group of a Squier complex. In this paper, we describe hyperplanes in these cube complexes. As a first application, we determine exactly when S(P,w) is a special cube complex, as defined by Haglund and Wise, so that the associated diagram group embeds into a right-angled Artin group. A particular feature of Squier complexes is that the intersections of hyperplanes are "ordered" by a relation . As a strong consequence on the geometry of S(P,w), we deduce, in finite dimensions, that its univeral cover isometrically embedds into a product of finitely-many trees with respect to the combinatorial metrics; in particular, we notice that (often) this allows to embed quasi-isometrically the associated diagram group into a product of finitely-many trees. Finally, we exhibit a class of hyperplanes inducing a decomposition of S(P,w) as a graph of spaces, and a fortiori a decomposition of the associated diagram group as a graph of groups, giving a new method to compute presentations of diagram groups. As an application, we associate a semigroup presentation P() to any finite interval graph , and we prove that the diagram group associated to P() (for a given base word) is isomorphic to the right-angled Artin group A().