Litcius/Paper detail

Forming a Mogi Doughnut in the Years Prior to and Immediately Before the 2014 <i>M</i>8.1 Iquique, Northern Chile, Earthquake

Bernd Schurr, Marcos Moreno, A. M. Tréhu, Jonathan Bedford, J. Kummerow, Shaoyang Li, Onno Oncken

2020Geophysical Research Letters60 citationsDOIOpen Access PDF

Abstract

Abstract Asperities are patches where the fault surfaces stick until they break in earthquakes. Locating asperities and understanding their causes in subduction zones is challenging because they are generally located offshore. We use seismicity, interseismic and coseismic slip, and the residual gravity field to map the asperity responsible for the 2014 M 8.1 Iquique, Chile, earthquake. For several years prior to the mainshock, seismicity occurred exclusively downdip of the asperity. Two weeks before the mainshock, a series of foreshocks first broke the upper plate then the updip rim of the asperity. This seismicity formed a ring around the slip patch (asperity) that later ruptured in the mainshock. The asperity correlated both with high interseismic locking and a circular gravity low, suggesting that it is controlled by geologic structure. Most features of the spatiotemporal seismicity pattern can be explained by a mechanical model in which a single asperity is stressed by relative plate motion.

Topics & Concepts

GeologyInduced seismicityAsperity (geotechnical engineering)SeismologySubductionSlip (aerodynamics)ForeshockTectonicsGeotechnical engineeringAftershockPhysicsThermodynamicsearthquake and tectonic studiesGeological and Geochemical AnalysisHigh-pressure geophysics and materials