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An Improved Upper Bound for Bootstrap Percolation in All Dimensions

Published online by Cambridge University Press:  17 June 2019

Andrew J. Uzzell*
Affiliation:
Department of Mathematics and Statistics, Grinnell College, Grinnell, IA 50112, USA

Abstract

In r-neighbour bootstrap percolation on the vertex set of a graph G, a set A of initially infected vertices spreads by infecting, at each time step, all uninfected vertices with at least r previously infected neighbours. When the elements of A are chosen independently with some probability p, it is natural to study the critical probability pc(G, r) at which it becomes likely that all of V(G) will eventually become infected. Improving a result of Balogh, Bollobás and Morris, we give a bound on the second term in the expansion of the critical probability when G = [n]d and dr ⩾ 2. We show that for all dr ⩾ 2 there exists a constant cd,r > 0 such that if n is sufficiently large, then

$$p_c (\left[ n \right]^d ,{\rm{ }}r){\rm{\le }}\left( {\frac{{\lambda (d,r)}}{{\log _{(r - 1)} (n)}} - \frac{{c_{d,r} }}{{(\log _{(r - 1)} (n))^{3/2} }}} \right)^{d - r + 1} ,$$

where λ(d, r) is an exact constant and log(k) (n) denotes the k-times iterated natural logarithm of n.

Type
Paper
Copyright
© Cambridge University Press 2019 

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Footnotes

This work was done while the author was at the University of Memphis.

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