Broken scaling in the Forest Fire Model

A. Honecker; A.M. Ferrenberg; B. Drossel; G. Pruessner; Gunnar Pruessner; Henrik Jeldtoft Jensen; J. Hoshen; K. Schenk; M.E.J. Newman; M.F. Sykes; P. Grassberger; S. Clar; S. Clar; S. Mertens

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Broken scaling in the Forest Fire Model

Authors: A. Honecker
A.M. Ferrenberg
B. Drossel
G. Pruessner
Gunnar Pruessner
Henrik Jeldtoft Jensen
J. Hoshen
K. Schenk
M.E.J. Newman
M.F. Sykes
P. Grassberger
S. Clar
S. Clar
S. Mertens
Publication date: 17 January 2002
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We investigate the scaling behavior of the cluster size distribution in the Drossel-Schwabl Forest Fire model (DS-FFM) by means of large scale numerical simulations, partly on (massively) parallel machines. It turns out that simple scaling is clearly violated, as already pointed out by Grassberger [P. Grassberger, J. Phys. A: Math. Gen. 26, 2081 (1993)], but largely ignored in the literature. Most surprisingly the statistics not seems to be described by a universal scaling function, and the scale of the physically relevant region seems to be a constant. Our results strongly suggest that the DS-FFM is not critical in the sense of being free of characteristic scales.Comment: 9 pages in RevTEX4 format (9 figures), submitted to PR

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