Optimal and Near-Optimal Constructions for Bootstrap Percolation in Hypercubes

Abstract

The r-neighbour bootstrap process on a graph G begins with a set of infected vertices; subsequently, healthy vertices become infected once they have at least r infected neighbours. The central extremal problem in bootstrap percolation is to determine the minimum cardinality of an initial infected set that eventually spreads to all vertices of G, denoted m(G;r). Morrison and Noel established a general lower bound on m(Qd;r), where Qd is the d-dimensional hypercube, and asked whether it is tight whenever d is sufficiently large with respect to r. This question was answered affirmatively for r≤ 3. In this paper, we show that m(Qd;4)=d(d2+3d+14)24+1, matching the bound in of Morrison and Noel, for infinitely many d. We also obtain, for general d, an upper bound on m(Qd;4) that differs from the Morrison--Noel lower bound by an additive O(d) term. Several key constructions in this paper were obtained with the assistance of AlphaEvolve.