Connectedness and Cycle Spaces of Friends-and-Strangers Graphs

Abstract

If X=(V(X),E(X)) and Y=(V(Y),E(Y)) are n-vertex graphs, then their friends-and-strangers graph FS(X,Y) is the graph whose vertices are the bijections from V(X) to V(Y) in which two bijections σ and σ' are adjacent if and only if there is an edge \a,b\∈ E(X) such that \σ(a),σ(b)\∈ E(Y) and σ'=σ (a\,\,b), where (a\,\,b) is the permutation of V(X) that swaps a and b. We prove general theorems that provide necessary and/or sufficient conditions for FS(X,Y) to be connected. As a corollary, we obtain a complete characterization of the graphs Y such that FS(Dandk,n,Y) is connected, where Dandk,n is a dandelion graph; this substantially generalizes a theorem of the first author and Kravitz in the case k=3. For specific choices of Y, we characterize the spider graphs X such that FS(X,Y) is connected. In a different vein, we study the cycle spaces of friends-and-strangers graphs. Naatz proved that if X is a path graph, then the cycle space of FS(X,Y) is spanned by 4-cycles and 6-cycles; we show that the same statement holds when X is a cycle and Y has domination number at least 3. When X is a cycle and Y has domination number at least 2, our proof sheds light on how walks in FS(X,Y) behave under certain Coxeter moves.