Lions and Contamination: Trees and General Graphs

Abstract

This paper investigates a special variant of a pursuit-evasion game called lions and contamination. In a graph where all vertices are initially contaminated, a set of lions traverses the graph, clearing the contamination from every vertex they visit. However, the contamination simultaneously spreads to any adjacent vertex not occupied by a lion. We analyze the relationships among the lion number L(G), monotone lion number Lm(G), and the graph's pathwidth pw(G). Our main results are as follows: (a) We prove a monotonicity property: for any graph G and its isometric subgraph H, L(H) L(G). (b) For trees T, we show that the lion number is tightly characterized by pathwidth, satisfying pw(T) L(T) pw(T)+1. (c) We provide a counterexample showing that the monotonicity property fails for arbitrary subgraphs. (d) We show that, in contrast to the tree case, pathwidth does not yield a general lower bound on L(G) for arbitrary graphs. (e) For any connected graph G, we prove the general upper bound L(G) pw(G)+1. (f) For the monotone variant, we establish the general lower bound pw(G) Lm(G). (g) Conversely, we show that Lm(G) 2pw(G)+2 holds for all connected graphs, which is best possible up to a small additive constant.