Small hitting sets for longest paths and cycles

Abstract

Motivated by an old question of Gallai (1966) on the intersection of longest paths in a graph and the well-known conjectures of Lov\'asz (1969) and Thomassen (1978) on the maximum length of paths and cycles in vertex-transitive graphs, we present improved bounds for the parameters lpt(G) and lct(G), defined as the minimum size of a set of vertices in a graph G hitting all longest paths (cycles, respectively). First, we show that every connected graph G on n vertices satisfies lpt(G) 8n, and lct(G) 8n if G is additionally 2-connected. This improves a sequence of earlier bounds for these problems, with the previous state of the art being O(n2/3). Second, we show that every connected graph G satisfies lpt(G) O(5/9), where denotes the maximum length of a path in G. As an immediate application of this latter bound, we present further progress towards Lov\'asz' and Thomassen's conjectures: We show that every connected vertex-transitive graph of order n contains a cycle (and path) of length (n9/14). This improves the previous best bound of the form (n13/21). Interestingly, our proofs make use of several concepts and results from structural graph theory, such as a result of Robertson and Seymour (1990) on transactions in societies and Tutte's 2-separator theorem.