The H-linkage problems in sparse robustly expanding digraphs

Abstract

The Nash-Williams conjecture establishes degree sequence conditions ensuring Hamilton cycles in digraphs. An asymptotic version of this conjecture for large digraphs was independently derived by several researchers. We strengthen these results by proving the following results under the same asymptotic degree sequence conditions. For any digraph H, a digraph D is (NH)-linked if there exists an integer l0 such that for any vertex set U of cardinality |V(H)| and every integer set N=\li\i=1|A(H)| with li≥ l0, D contains an H-subdivision with U as branch-vertex set and the values in N specifying the lengths of the subdivided paths. Let D be a sufficiently large digraph of order n with the out-degree sequence d1+≤·s≤ dn+ and the in-degree sequence d1-≤·s≤ dn-. We prove that if for every γ∈(0, 1) and every integer 0≤ i<n/2, the following conditions hold: (i) di+≥ i+γ n or dn-i-γ n-≥ n-i, and (ii) di-≥ i+γ n or dn-i-γ n+≥ n-i, then D is (NH)-linked, and also admits a perfect H-subdivision tiling with subdivision orders \n1, …, nk\, where each ni≥ C0 for some integer C0.