An efficient asymmetric removal lemma and its limitations

Abstract

The triangle removal states that if G contains n2 edge-disjoint triangles, then G contains δ()n3 triangles. Unfortunately, there are no sensible bounds on the order of growth of δ(), and at any rate, it is known that δ() is not polynomial in . Csaba recently obtained an asymmetric variant of the triangle removal, stating that if G contains n2 edge-disjoint triangles, then G contains 2-poly(1/)· n5 copies of C5. To this end, he devised a new variant of Szemer\'edi's regularity lemma. We obtain the following results: - We first give a regularity-free proof of Csaba's theorem, which improves the number of copies of C5 to the optimal number poly()· n5. - We say that H is K3-abundant if every graph containing n2 edge-disjoint triangles has poly()· n|V(H)| copies of H. It is easy to see that a K3-abundant graph must be triangle-free and tripartite. Given our first result, it is natural to ask if all triangle-free tripartite graphs are K3-abundant. Our second result is that assuming a well-known conjecture of Ruzsa in additive number theory, the answer to this question is negative. Our proofs use a mix of combinatorial, number-theoretic, probabilistic, and Ramsey-type arguments.