English

$\ell$-degree Tur\'an density

Combinatorics 2014-10-15 v2

Abstract

Let HnH_n be a kk-graph on nn vertices. For 0<k0 \le \ell <k and an \ell-subset TT of V(Hn)V(H_n), define the degree deg(T)\deg(T) of TT to be the number of (k)(k-\ell)-subsets~SS such that STS \cup T is an edge in~HnH_n. Let the minimum \ell-degree of HnH_n be δ(Hn)=min{deg(T):TV(Hn)\delta_{\ell}(H_n) = \min \{ \deg(T) : T \subseteq V(H_n) and T=}|T|=\ell\}. Given a family F\mathcal{F} of kk-graphs, the \ell-degree Tur\'an number ex(n,F)\text{ex}_{\ell}(n, \mathcal{F}) is the largest δ(Hn)\delta_{\ell}(H_n) over all F\mathcal{F}-free kk-graphs HnH_n on nn vertices. Hence, ex0(n,F)\text{ex}_0(n, \mathcal{F}) is the Tur\'an number. We define \ell-degree Tur\'an density to be πk(F)=lim supnex(n,F)(nk).\pi^k_{\ell}(\mathcal{F}) = \limsup_{n \rightarrow \infty} \frac{\text{ex}_{\ell}(n, \mathcal{F} )}{ \binom{n- \ell}{k}}. In this paper, we show that for k>>1k> \ell >1, the set of πk(F)\pi_{\ell}^k(\mathcal{F}) is dense in the interval [0,1)[0,1). Hence, there is no "jump" for \ell-degree Tur\'an density when k>>1k>\ell >1. We also give a lower bound on πk(F)\pi_{\ell}^k(\mathcal{F}) in terms of an ordinary Tur\'an density.

Keywords

Cite

@article{arxiv.1210.5726,
  title  = {$\ell$-degree Tur\'an density},
  author = {Allan Lo and Klas Markström},
  journal= {arXiv preprint arXiv:1210.5726},
  year   = {2014}
}

Comments

Updated. Now published in SIAM J. Discrete Math. 28 (2014), 1214-1225

R2 v1 2026-06-21T22:25:24.238Z