On the Hypergraph Nash-Williams' Conjecture

Abstract

In 2014, Keevash proved the existence of (n,q,r)-Steiner systems (equivalently Kqr-decompositions of Knr) for all large enough n satisfying the necessary divisibility conditions. In 2021, Glock, K\"uhn, and Osthus proposed a generalization of this result. Namely they conjectured a hypergraph version of Nash-Williams' Conjecture positing that if a Kqr-divisible r-graph G on n vertices has minimum (r-1)-degree (denoted δ(G) hereafter) at least (1-r(1qr-1)) · n, then G admits a Kqr-decomposition. The best known progress on this conjecture dates to the second proof of the Existence Conjecture by Glock, K\"uhn, Lo, and Osthus wherein they showed that δ(G) (1-cq2r)· n suffices for large enough n, where c is a constant depending on r but not q. As for the fractional relaxation, the best known bound is due to Delcourt, Lesgourgues, and the second author, who proved that δ(G) (1-cqr-1 + o(1))· n guarantees a Kqr-fractional decomposition. We prove that for every integer r 2, there exists a real c>0 such that if a Kqr-divisible r-graph G satisfies δ(G) \ δKqr* + ,~~1 -cqr-1 \ · n, then G admits a Kqr-decomposition for all large enough n, where δKqr* denotes the fractional Kqr-decomposition threshold. Combined with the fractional result above, this proves that (1-cqr-1 + o(1))· n suffices for the Hypergraph Nash-Williams' Conjecture, approximately confirming the correct order of q. Our proof uses the newly developed method of refined absorption; we also develop a non-uniform Tur\'an theory to prove the existence of many embeddings of absorbers which may be of independent interest.

0

Turn this paper into a full lesson

ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.

Discussion (0)

Sign in to join the discussion.

Loading comments…