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Authordc.contributor.authorSaltiel, Seth 
Authordc.contributor.authorMittal, Tushar 
Authordc.contributor.authorCrempien, Jorge G. F. 
Authordc.contributor.authorCampos Muñoz, Jaime 
Admission datedc.date.accessioned2021-03-15T20:55:38Z
Available datedc.date.available2021-03-15T20:55:38Z
Publication datedc.date.issued2020
Cita de ítemdc.identifier.citationFrontiers in Earth Science September 2020 | Volume 8 | Article 373es_ES
Identifierdc.identifier.other10.3389/feart.2020.00373
Identifierdc.identifier.urihttps://repositorio.uchile.cl/handle/2250/178694
Abstractdc.description.abstractFracture mechanics theory and seismological observations suggest that slip-rate is constantly changing during earthquake rupture, including dramatic acceleration from static conditions to high velocity sliding followed by deceleration and arrest. This slip history is partly determined by a complex frictional evolution, including overcoming peak friction, rapid weakening, and re-strengthening (or healing). Recent experimental developments have allowed friction evolution measurements under realistic slip histories reaching high co-seismic slip-rates of meters per second. Theoretical work has focused on describing the observed steady-state weakening at these high-velocities, but the transient behavior has only been fit by direct parameterizations without state variable dependence, needed to simulate arbitrary slip-histories. Commonly used forms of rate-state friction (RSF) are based on low-velocity, step-change experiments and have been shown to not fit the entire frictional evolution using a single set of realistic parameters. Their logarithmic form precludes zero fault slip-rate, assuming it is never truly static, thus does not capture slip initiation phenomena that might contribute to nucleation behavior. Inverting high slip-rate and friction data from different types of experiments, we show that RSF can work by using parameter ranges far from typical low-velocity values. In comparison, we introduce "bristle-state" friction (BSF) models, developed by control-system engineers to predict the transient frictional evolution during arbitrary stressing, especially reversals through static conditions. Although BSF models were also designed for low-velocities, we show that their form provides advantages for fitting frictional evolution measurements under high slip-rate, long-displacement, non-trivial slip histories, especially during the initial strengthening stage.es_ES
Patrocinadordc.description.sponsorshipLamont-Doherty Fellowship in Earth and Environmental Sciences National Science Foundation (NSF) 1615203 National Research Center for Integrated Natural Disaster Management ANID/FONDAP/15110017 Andean Geothermal Center of Excellence, CEGA 15090013es_ES
Lenguagedc.language.isoenes_ES
Publisherdc.publisherFrontiers Mediaes_ES
Type of licensedc.rightsAttribution-NonCommercial-NoDerivs 3.0 Chile*
Link to Licensedc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/3.0/cl/*
Sourcedc.sourceFrontiers in Earth Sciencees_ES
Keywordsdc.subjectEarthquake nucleationes_ES
Keywordsdc.subjectEarthquake rupture dynamicses_ES
Keywordsdc.subjectFriction lawses_ES
Keywordsdc.subjectTransient evolutiones_ES
Keywordsdc.subjectHigh-velocity experimentses_ES
Keywordsdc.subjectState-variable modelses_ES
Keywordsdc.subjectSliding regimeses_ES
Títulodc.title"Bristle-State" Friction: Modeling Slip Initiation and Transient Frictional Evolution From High-Velocity Earthquake Rupture Experimentses_ES
Document typedc.typeArtículo de revistaes_ES
dcterms.accessRightsdcterms.accessRightsAcceso Abierto
Catalogueruchile.catalogadorlajes_ES
Indexationuchile.indexArtículo de publicación ISI
Indexationuchile.indexArtículo de publicación SCOPUS


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