Static Stress Increase in the Outer Forearc Produced by MW 8.2 September 8, 2017 Mexico Earthquake and its Relation to the Gravity Signal

An Mw 8.2 earthquake affected on September 8, 2017 the Cocos plate beneath the Caribbean plate next to the transform contact with the North American plate across the Tehuantepec gap, one of the two gaps that exist along the Mexican subduction zone offshore Chiapas. The epicenter occurred at a depth...

Descripción completa

Guardado en:
Detalles Bibliográficos
Publicado: 2018
Materias:
Chiapas earthquake
Coulomb static stress
extensional faults
satellite gravimetry
Dehydration
Faulting
Liquid sloshing
Plates (structural components)
Earth gravity field models
Extensional faults
Interplate earthquakes
Megathrust earthquakes
Mexican subduction zone
Satellite gravimetries
Seismic rupture propagation
Static stress
Earthquakes
Coulomb criterion
earthquake event
earthquake magnitude
extensional tectonics
fault
gravimetry
satellite altimetry
static response
Chiapas
Mexico [North America]
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00334553_v175_n8_p2575_Spagnotto
http://hdl.handle.net/20.500.12110/paper_00334553_v175_n8_p2575_Spagnotto
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paper:paper_00334553_v175_n8_p2575_Spagnotto
record_format dspace
spelling paper:paper_00334553_v175_n8_p2575_Spagnotto2023-06-08T15:00:33Z Static Stress Increase in the Outer Forearc Produced by MW 8.2 September 8, 2017 Mexico Earthquake and its Relation to the Gravity Signal Chiapas earthquake Coulomb static stress extensional faults satellite gravimetry Dehydration Faulting Liquid sloshing Plates (structural components) Earth gravity field models Extensional faults Interplate earthquakes Megathrust earthquakes Mexican subduction zone Satellite gravimetries Seismic rupture propagation Static stress Earthquakes Coulomb criterion earthquake event earthquake magnitude extensional tectonics fault gravimetry satellite altimetry static response Chiapas Mexico [North America] An Mw 8.2 earthquake affected on September 8, 2017 the Cocos plate beneath the Caribbean plate next to the transform contact with the North American plate across the Tehuantepec gap, one of the two gaps that exist along the Mexican subduction zone offshore Chiapas. The epicenter occurred at a depth of 47 km and was associated with a highly steep normal fault parallel to the trench. The origin can be related to slab pull forces, dehydration processes and reactivation of outer rise faults. This earthquake produced positive changes in the Coulomb static stress, which would favor the development of thrust displacements along the interplate contact across the Tehuantepec gap instead of liberating tensions accumulated on it for decades. In the case that stresses were not released steadily in the future, a thrusting-related event with a magnitude of Mw 7.9 or higher could be expected after the September 8, 2017 Chiapas earthquake. However, the differential weight of the forearc offshore (that contains a region with a high positive gravity gradient) could inhibit rupture propagation to the coast precluding higher magnitudes. Combined and satellite only earth gravity field models show a highly heterogeneous density structure along the forearc of the North America-Caribbean plates and in particular at the studied zone. Maximum displacements in the rupture zone correlate to minimum gravity-derived anomalies showing a probable relationship between the differential weight of the forearc structure and the extensional faulting affecting the bending of the Cocos plate at depth. In this sense, variable sediment thicknesses over the forearc, and a high gravity gradient zone parallel to the trench in the outer forearc, could be reflecting physical heterogeneities that influence the propagation of the rupture zone. Additionally, to the north, a highly positive gradient signal related to the subducted Tehuantepec Fz projection beneath the North American plate marks the ending of the main slip patch acting as a barrier to the seismic rupture propagation. This event exemplifies (1) how extensional ruptures in the downgoing slab of a subduction zone can increment accumulated elastic strain across a seismic gap instead of liberating tensions, (2) that rupture propagation for this intraplate event was probably controlled (at shallow depths) by the density structure of the forearc, similarly to recent interplate earthquakes along the Chilean margin; (3) how a low gravity gradient signal and low density structures identified from the inversion model in the region of the outer forearc, where the normal stress increased after the main seismic event, suggest a higher risk of occurrence of a great megathrust earthquake. © 2018, Springer Nature Switzerland AG. 2018 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00334553_v175_n8_p2575_Spagnotto http://hdl.handle.net/20.500.12110/paper_00334553_v175_n8_p2575_Spagnotto
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Chiapas earthquake
Coulomb static stress
extensional faults
satellite gravimetry
Dehydration
Faulting
Liquid sloshing
Plates (structural components)
Earth gravity field models
Extensional faults
Interplate earthquakes
Megathrust earthquakes
Mexican subduction zone
Satellite gravimetries
Seismic rupture propagation
Static stress
Earthquakes
Coulomb criterion
earthquake event
earthquake magnitude
extensional tectonics
fault
gravimetry
satellite altimetry
static response
Chiapas
Mexico [North America]
spellingShingle Chiapas earthquake
Coulomb static stress
extensional faults
satellite gravimetry
Dehydration
Faulting
Liquid sloshing
Plates (structural components)
Earth gravity field models
Extensional faults
Interplate earthquakes
Megathrust earthquakes
Mexican subduction zone
Satellite gravimetries
Seismic rupture propagation
Static stress
Earthquakes
Coulomb criterion
earthquake event
earthquake magnitude
extensional tectonics
fault
gravimetry
satellite altimetry
static response
Chiapas
Mexico [North America]
Static Stress Increase in the Outer Forearc Produced by MW 8.2 September 8, 2017 Mexico Earthquake and its Relation to the Gravity Signal
topic_facet Chiapas earthquake
Coulomb static stress
extensional faults
satellite gravimetry
Dehydration
Faulting
Liquid sloshing
Plates (structural components)
Earth gravity field models
Extensional faults
Interplate earthquakes
Megathrust earthquakes
Mexican subduction zone
Satellite gravimetries
Seismic rupture propagation
Static stress
Earthquakes
Coulomb criterion
earthquake event
earthquake magnitude
extensional tectonics
fault
gravimetry
satellite altimetry
static response
Chiapas
Mexico [North America]
description An Mw 8.2 earthquake affected on September 8, 2017 the Cocos plate beneath the Caribbean plate next to the transform contact with the North American plate across the Tehuantepec gap, one of the two gaps that exist along the Mexican subduction zone offshore Chiapas. The epicenter occurred at a depth of 47 km and was associated with a highly steep normal fault parallel to the trench. The origin can be related to slab pull forces, dehydration processes and reactivation of outer rise faults. This earthquake produced positive changes in the Coulomb static stress, which would favor the development of thrust displacements along the interplate contact across the Tehuantepec gap instead of liberating tensions accumulated on it for decades. In the case that stresses were not released steadily in the future, a thrusting-related event with a magnitude of Mw 7.9 or higher could be expected after the September 8, 2017 Chiapas earthquake. However, the differential weight of the forearc offshore (that contains a region with a high positive gravity gradient) could inhibit rupture propagation to the coast precluding higher magnitudes. Combined and satellite only earth gravity field models show a highly heterogeneous density structure along the forearc of the North America-Caribbean plates and in particular at the studied zone. Maximum displacements in the rupture zone correlate to minimum gravity-derived anomalies showing a probable relationship between the differential weight of the forearc structure and the extensional faulting affecting the bending of the Cocos plate at depth. In this sense, variable sediment thicknesses over the forearc, and a high gravity gradient zone parallel to the trench in the outer forearc, could be reflecting physical heterogeneities that influence the propagation of the rupture zone. Additionally, to the north, a highly positive gradient signal related to the subducted Tehuantepec Fz projection beneath the North American plate marks the ending of the main slip patch acting as a barrier to the seismic rupture propagation. This event exemplifies (1) how extensional ruptures in the downgoing slab of a subduction zone can increment accumulated elastic strain across a seismic gap instead of liberating tensions, (2) that rupture propagation for this intraplate event was probably controlled (at shallow depths) by the density structure of the forearc, similarly to recent interplate earthquakes along the Chilean margin; (3) how a low gravity gradient signal and low density structures identified from the inversion model in the region of the outer forearc, where the normal stress increased after the main seismic event, suggest a higher risk of occurrence of a great megathrust earthquake. © 2018, Springer Nature Switzerland AG.
title Static Stress Increase in the Outer Forearc Produced by MW 8.2 September 8, 2017 Mexico Earthquake and its Relation to the Gravity Signal
title_short Static Stress Increase in the Outer Forearc Produced by MW 8.2 September 8, 2017 Mexico Earthquake and its Relation to the Gravity Signal
title_full Static Stress Increase in the Outer Forearc Produced by MW 8.2 September 8, 2017 Mexico Earthquake and its Relation to the Gravity Signal
title_fullStr Static Stress Increase in the Outer Forearc Produced by MW 8.2 September 8, 2017 Mexico Earthquake and its Relation to the Gravity Signal
title_full_unstemmed Static Stress Increase in the Outer Forearc Produced by MW 8.2 September 8, 2017 Mexico Earthquake and its Relation to the Gravity Signal
title_sort static stress increase in the outer forearc produced by mw 8.2 september 8, 2017 mexico earthquake and its relation to the gravity signal
publishDate 2018
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00334553_v175_n8_p2575_Spagnotto
http://hdl.handle.net/20.500.12110/paper_00334553_v175_n8_p2575_Spagnotto
_version_ 1768541883235041280

Ejemplares similares