Spanning H-subdivisions and perfect H-subdivision tilings in dense digraphs
Abstract
Given a (di)graph H, we say that a (di)graph H is an H-subdivision if H is obtained from H by replacing one or more edges with internally vertex-disjoint path(s). Pavez-Sign\'e conjectured that for every >0, there exists a constant C0>0 such that for every graph H with h edges and no isolated vertices, if G is a graph on n≥ C0h vertices and minimum degree δ(G)≥(1+)n2, then G contains a spanning H-subdivision. This conjecture was later resolved by Lee [European J. Combin. 124 (2025), 104059]. In this paper, we strengthen Lee's result. Specifically, we prove that for any digraph D on n≥ C0h vertices, if the minimum semi-degree of D is at least n+h2-1, then D contains a spanning H-subdivision. The lower bound on the minimum semi-degree is best possible. Furthermore, we show that there exist constants C>0 and α, β∈(0, 1) such that for any integer partition n=n1+·s+nm≥ Cm with ni≥|V(H)|+3h for each i, and Σni<α nni≤β n, if a digraph of order n≥ Cm has minimum semi-degree at least n+m+h2-1, then it contains m vertex-disjoint H-subdivisions whose orders are n1, …, nm, respectively. The bound n+m+h2-1 is also optimal. This work partly answers a conjecture of Lee [Combin. Probab. Comput. 34 (2025), 421--444] and generalizes a recent result from the same paper.
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