Graf, Robert A forest-fire model on the upper half-plane. (English) Zbl 1291.82037 Electron. J. Probab. 19, Paper No. 8, 27 p. (2014). Summary: We consider a discrete forest-fire model on the upper half-plane of the two-dimensional square lattice. Each site can have one of the following two states: “vacant” or “occupied by a tree”. At the starting time all sites are vacant. Then the process is governed by the following random dynamics: Trees grow at rate 1, independently for all sites. If an occupied cluster reaches the boundary of the upper half plane or if it is about to become infinite, the cluster is instantaneously destroyed, i.e. all of its sites turn vacant. Additionally, we demand that the model is invariant under translations along the \(x\)-axis. We prove that such a model exists and arises naturally as a subseqential limit of forest-fire processes in finite boxes when the box size tends to infinity. Moreover, the model exhibits a phase transition in the following sense: There exists a critical time \(t_c\) (which corresponds with the critical probability \(p_c\) in ordinary site percolation by \(1 - e^{-t_c} = p_c\)) such that before \(t_c\), only sites close to the boundary have been affected by destruction, whereas after \(t_c\), sites on the entire half-plane have been affected by destruction. Cited in 2 Documents MSC: 82B26 Phase transitions (general) in equilibrium statistical mechanics 82B27 Critical phenomena in equilibrium statistical mechanics 60K35 Interacting random processes; statistical mechanics type models; percolation theory 82C22 Interacting particle systems in time-dependent statistical mechanics 82B43 Percolation Keywords:forest-fire model; upper half-plane; self-organized criticality; phase transition × Cite Format Result Cite Review PDF Full Text: DOI