Minimum degree conditions for tight Hamilton cycles

Abstract

We develop a new framework to study minimum d-degree conditions in k-uniform hypergraphs, which guarantee the existence of a tight Hamilton cycle. Our main theoretical result deals with the typical absorption, path cover and connecting arguments for all k and d at once, and thus sheds light on the underlying structural problems. Building on this, we show that one can study minimum d-degree conditions of k-uniform tight Hamilton cycles by focusing on the inner structure of the neighbourhoods. This reduces the matter to an Erdos--Gallai-type question for (k-d)-uniform hypergraphs, which is of independent interest. Once this framework is established, we can easily derive two new bounds. Firstly, we extend a classic result of R\"odl, Ruci\'nski and Szemer\'edi for d=k-1 by determining asymptotically best possible degree conditions for d = k-2 and all k 3. This was proved independently by Polcyn, Reiher, R\"odl and Sch\"ulke. Secondly, we provide a general upper bound of 1-1/(2(k-d)) for the tight Hamilton cycle d-degree threshold in k-uniform hypergraphs, thus narrowing the gap to the lower bound of 1-1/k-d due to Han and Zhao.