On graphs embeddable in a layer of a hypercube and their extremal numbers

Abstract

A graph is cubical if it is a subgraph of a hypercube. For a cubical graph H and a hypercube Qn, ex(Qn, H) is the largest number of edges in an H-free subgraph of Qn. If ex(Qn, H) is equal to a positive proportion of the number of edges in Qn, H is said to have positive Tur\'an density in a hypercube; otherwise it has zero Tur\'an density. Determining ex(Qn, H) and even identifying whether H has positive or zero Tur\'an density remains a widely open question for general H. In this paper we focus on layered graphs, i.e., graphs that are contained in an edge-layer of some hypercube. Graphs H that are not layered have positive Tur\'an density because one can form an H-free subgraph of Qn consisting of edges of every other layer. For example, a 4-cycle is not layered and has positive Tur\'an density. However, in general it is not obvious what properties layered graphs have. We give a characterisation of layered graphs in terms of edge-colorings. We show that most non-trivial subdivisions have zero Tur\'an density, extending known results on zero Tur\'an density of even cycles of length at least 12 and of length 8. However, we prove that there are cubical graphs of girth 8 that are not layered and thus having positive Tur\'an density. The cycle of length 10 remains the only cycle for which it is not known whether its Tur\'an density is positive or not. We prove that ex(Qn, C10)= (n2n/ a n), for a constant a, showing that the extremal number for a 10-cycle behaves differently from any other cycle of zero Tur\'an density.