The Erdős-Hajnal High-Girth Subgraph Conjecture Holds in the Polynomial Chromatic-Sparsity Regime

Abstract

For a graph G put hr(G)=χ(H):H⊂eq G,girth(H) r. Erdős and Hajnal asked whether hr(G)∞ as χ(G)∞, for every fixed r4. We prove this in every fixed polynomial edge-density regime: for all r4, k2, P,C>0, there is M=Mr,k(P,C) such that χ(G) M,\ e(G) Cχ(G)P hr(G) k. Quantitatively, after replacing P by P2 and C by C2, Mr,k(P,C) !(Or,k((P+2+(C2))2)), and consequently the same conclusion holds throughout the quasi-polynomial range e(G) (C0(χ(G))a),\ 1 < a < 3/2, for all sufficiently large χ(G). In each fixed polynomial-density regime we also obtain fP,C(k,r) kOr,P,C(1). The proof combines a chromatic-defect random extraction lemma, compact and near-quadratic sparse-core bases, and a peeling/thinning bootstrap increasing the admissible edge exponent by 1/(r-1). We also prove structural saturation results for possible counterexamples, including Moore-strength exact-cycle packings and quadratic saturation in projected colour-pair space. Finally, writing hr f(G)=χ f(H):H⊂eq G,girth(H) r, we develop a fractional random-extraction framework based on Mohar-Wu preservation. We prove sufficient cheap-cycle-killing criteria and verify them for several structured families, including clique-organised families, line graphs of incidence graphs of equal-order generalized quadrangles and generalized hexagons, and the Bohman-Keevash tracking-time triangle-free-process graph. We also isolate a density-free obstruction that any proof using this fractional surgery route must overcome.