by BOTTIGLIERI M., DE ARCANGELIS Lucilla, GODANO Cataldo, LIPPIELLO Eugenio
Abstract:
The interevent time distribution characterizes the temporal occurrence in seismic catalogs. Universal scaling properties of this distribution have been evidenced for entire catalogs and seismic sequences. Recently, these universal features have been questioned and some criticisms have been raised. We investigate the existence of universal scaling properties by analyzing a Californian catalog and by means of numerical simulations of an epidemic-type model. We show that the interevent time distribution exhibits a universal behavior over the entire temporal range if four characteristic times are taken into account. The above analysis allows us to identify the scaling form leading to universal behavior and explains the observed deviations. Furthermore, it provides a tool to identify the dependence on the mainshock magnitude of the c parameter that fixes the onset of the power law decay in the Omori law.
Reference:
Multiple-time scaling and universal behaviour of the earthquake inter-event time distribution (BOTTIGLIERI M., DE ARCANGELIS Lucilla, GODANO Cataldo, LIPPIELLO Eugenio), In PHYSICAL REVIEW LETTERS, volume 104, 2010. (Articolo in rivista)
Bibtex Entry:
@article{mil10,
author = {BOTTIGLIERI M., and DE ARCANGELIS Lucilla, and GODANO Cataldo, and LIPPIELLO Eugenio,},
pages = {158501-158504},
title = {Multiple-time scaling and universal behaviour of the earthquake inter-event time distribution},
volume = {104},
note = {Articolo in rivista},
issn = {0031-9007},
journal = {PHYSICAL REVIEW LETTERS},
year = {2010},
wosId = {WOS:000277001700052},
scopusId = {2-s2.0-77951046632},
abstract = {The interevent time distribution characterizes the temporal occurrence in seismic catalogs. Universal
scaling properties of this distribution have been evidenced for entire catalogs and seismic sequences.
Recently, these universal features have been questioned and some criticisms have been raised. We
investigate the existence of universal scaling properties by analyzing a Californian catalog and by means
of numerical simulations of an epidemic-type model. We show that the interevent time distribution
exhibits a universal behavior over the entire temporal range if four characteristic times are taken into
account. The above analysis allows us to identify the scaling form leading to universal behavior and
explains the observed deviations. Furthermore, it provides a tool to identify the dependence on the
mainshock magnitude of the c parameter that fixes the onset of the power law decay in the Omori law.}
}