(Theta, triangle)-free and (even hole, K4)-free graphs. Part 2 : bounds on treewidth

Abstract

A theta is a graph made of three internally vertex-disjoint chordless paths P1 = a … b, P2 = a … b, P3 = a … b of length at least~2 and such that no edges exist between the paths except the three edges incident to a and the three edges incident to b. A pyramid is a graph made of three chordless paths P1 = a … b1, P2 = a … b2, P3 = a … b3 of length at least~1, two of which have length at least 2, vertex-disjoint except at a, and such that b1b2b3 is a triangle and no edges exist between the paths except those of the triangle and the three edges incident to~a. An even hole is a chordless cycle of even length. For three non-negative integers i≤ j≤ k, let Si,j,k be the tree with a vertex v, from which start three paths with i, j, and k edges respectively. We denote by Kt the complete graph on t vertices. We prove that for all non-negative integers i, j, k, the class of graphs that contain no theta, no K3, and no Si, j, k as induced subgraphs have bounded treewidth. We prove that for all non-negative integers i, j, k, t, the class of graphs that contain no even hole, no pyramid, no Kt, and no Si, j, k as induced subgraphs have bounded treewidth. To bound the treewidth, we prove that every graph of large treewidth must contain a large clique or a minimal separator of large cardinality.