On the Minimal Edge Density of K4-free 6-critical Graphs

Abstract

Kostochka and Yancey resolved a famous conjecture of Ore on the asymptotic density of k-critical graphs by proving that every k-critical graph G satisfies |E(G)| ≥ (k2 - 1k-1)|V(G)| - k(k-3)2(k-1). The class of graphs for which this bound is tight, k-Ore graphs, contain a notably large number of Kk-2-subgraphs. Subsequent work attempted to determine the asymptotic density for k-critical graphs that do not contain large cliques as subgraphs, but only partial progress has been made on this problem. The second author showed that if G is 5-critical and has no K3-subgraphs, then for = 1/84, |E(G)| ≥ (94 + )|V(G)| - 54. It has also been shown that for all k ≥ 33, there exists k > 0 such that k-critical graphs with no Kk-2-subgraphs satisfy |E(G)| ≥ (k2 - 1k-1 + k)|V(G)| - k(k-3)2(k-1). In this work, we develop general structural results that are applicable to resolving the remaining difficult cases 6 ≤ k ≤ 32. We apply our results to carefully analyze the structure of 6-critical graphs and use a discharging argument to show that for 6 = 1/1050, 6-critical graphs with no K4 subgraph satisfy |E(G)| ≥ ( k2 - 1k-1 + 6 ) |V(G)| - k(k-3)2(k-1).