Crux and long cycles in graphs

Abstract

We introduce a notion of the crux of a graph G, measuring the order of a smallest dense subgraph in G. This simple-looking notion leads to some generalisations of known results about cycles, offering an interesting paradigm of `replacing average degree by crux'. In particular, we prove that every graph contains a cycle of length linear in its crux. Long proved that every subgraph of a hypercube Qm (resp. discrete torus C3m) with average degree d contains a path of length 2d/2 (resp. 2d/4), and conjectured that there should be a path of length 2d-1 (resp. 3d/2-1). As a corollary of our result, together with isoperimetric inequalities, we close these exponential gaps giving asymptotically optimal bounds on long paths in hypercubes, discrete tori, and more generally Hamming graphs. We also consider random subgraphs of C4-free graphs and hypercubes, proving near optimal bounds on lengths of long cycles.