Clique factors in Kneser graphs

Abstract

For k,n∈ N, the Kneser graph K(n,k) is the graph with vertex set V=[n](k) and edge set E=\\x,y\ ∈ V(2): x y=\. Chen proved that for n≥ 3k, Kneser graphs are Hamiltonian. Similarly as for graphs with Hajnal's and Szemer\'edi's result about a minimum degree condition for clique factors and the P\'osa-Seymour Conjecture together with its solution for large graphs due to Koml\'os, S\'ark\"ozy, and Szemer\'edi, the next step is to ask for clique factors and powers of Hamiltonian cycles in Kneser graphs. For k,∈ N, let n(k,) be the smallest integer such that for n≥ n(k,), K(n,k) contains the -th power of a Hamiltonian cycle. Katona conjectured that for all but finitely many exceptions, n(k,)=(+1)k+1 holds. In particular, it would be interesting to know whether n(k,) is linear in k (for fixed ). So far this is not known for k≥ 2. In this note, we take a first step towards such a linear bound by proving that for ∈ N, k≥ and n≥ 3k, all but at most -1 vertices of K(n,k) can be partitioned into cliques of size . Further, we use our methods to extend a short proof due to Chen and F\"uredi that K(n,k) is Hamiltonian for n≥ 3k and k n to all n≥ 4k if k≥ 4.