Structural control and system-level behavior of the seismic cycle at the Nankai Trough

Structural control and system-level behavior of the seismic cycle at the Nankai Trough

Abstract The Nankai Trough in Southwest Japan exhibits a wide spectrum of fault slip, with long-term and short-term slow-slip events, slow and fast earthquakes, all associated with different segments down the plate interface. Frictional and viscous properties vary depending on rock type, temperature...

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Main Authors: Qibin Shi, Sylvain Barbot, Shengji Wei, Paul Tapponnier, Takanori Matsuzawa, Bunichiro Shibazaki
Format: Article
Language:English
Published: SpringerOpen 2020-03-01
Series:Earth, Planets and Space
Subjects:
Friction
Rheology
Subduction zones
Online Access:http://link.springer.com/article/10.1186/s40623-020-1145-0
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spelling doaj-8b81c0c0ff0544759fc7d28880ca0d9a2020-11-25T01:31:23ZengSpringerOpenEarth, Planets and Space1880-59812020-03-0172113110.1186/s40623-020-1145-0Structural control and system-level behavior of the seismic cycle at the Nankai TroughQibin Shi0Sylvain Barbot1Shengji Wei2Paul Tapponnier3Takanori Matsuzawa4Bunichiro Shibazaki5Earth Observatory of Singapore, Asian School of the Environment, Nanyang Technological UniversityDepartment of Earth Sciences, University of Southern CaliforniaEarth Observatory of Singapore, Asian School of the Environment, Nanyang Technological UniversityInstitute of Crustal Dynamics, China Earthquake AdministrationNational Research Institute for Earth Science and Disaster ResilienceInternational Institute of Seismology and Earthquake Engineering, Building Research InstituteAbstract The Nankai Trough in Southwest Japan exhibits a wide spectrum of fault slip, with long-term and short-term slow-slip events, slow and fast earthquakes, all associated with different segments down the plate interface. Frictional and viscous properties vary depending on rock type, temperature, and pressure. However, what controls the down-dip segmentation of the Nankai subduction zone megathrust and how the different domains of the subduction zone interact during the seismic cycle remains unclear. Here, we model a representative cross-section of the Nankai subduction zone offshore Shikoku Island where the frictional behavior is dictated by the structure and composition of the overriding plate. The intersections of the megathrust with the accretionary prism, arc crust, metamorphic belt, and upper mantle down to the asthenosphere constitute important domain boundaries that shape the characteristics of the seismic cycle. The mechanical interactions between neighboring fault segments and the impact from the long-term viscoelastic flow strongly modulate the recurrence pattern of earthquakes and slow-slip events. Afterslip penetrates down-dip and up-dip into slow-slip regions, leading to accelerated slow-slip cycles at depth and long-lasting creep waves in the accretionary prism. The trench-ward migrating locking boundary near the bottom of the seismogenic zone progressively increases the size of long-term slow-slip events during the interseismic period. Fault dynamics is complex and potentially tsunami-genic in the accretionary region due to low friction, off-fault deformation, and coupling with the seismogenic zone.http://link.springer.com/article/10.1186/s40623-020-1145-0FrictionRheologySubduction zones
collection DOAJ
language English
format Article
sources DOAJ
author Qibin Shi
Sylvain Barbot
Shengji Wei
Paul Tapponnier
Takanori Matsuzawa
Bunichiro Shibazaki
spellingShingle Qibin Shi
Sylvain Barbot
Shengji Wei
Paul Tapponnier
Takanori Matsuzawa
Bunichiro Shibazaki
Structural control and system-level behavior of the seismic cycle at the Nankai Trough
Earth, Planets and Space
Friction
Rheology
Subduction zones
author_facet Qibin Shi
Sylvain Barbot
Shengji Wei
Paul Tapponnier
Takanori Matsuzawa
Bunichiro Shibazaki
author_sort Qibin Shi
title Structural control and system-level behavior of the seismic cycle at the Nankai Trough
title_short Structural control and system-level behavior of the seismic cycle at the Nankai Trough
title_full Structural control and system-level behavior of the seismic cycle at the Nankai Trough
title_fullStr Structural control and system-level behavior of the seismic cycle at the Nankai Trough
title_full_unstemmed Structural control and system-level behavior of the seismic cycle at the Nankai Trough
title_sort structural control and system-level behavior of the seismic cycle at the nankai trough
publisher SpringerOpen
series Earth, Planets and Space
issn 1880-5981
publishDate 2020-03-01
description Abstract The Nankai Trough in Southwest Japan exhibits a wide spectrum of fault slip, with long-term and short-term slow-slip events, slow and fast earthquakes, all associated with different segments down the plate interface. Frictional and viscous properties vary depending on rock type, temperature, and pressure. However, what controls the down-dip segmentation of the Nankai subduction zone megathrust and how the different domains of the subduction zone interact during the seismic cycle remains unclear. Here, we model a representative cross-section of the Nankai subduction zone offshore Shikoku Island where the frictional behavior is dictated by the structure and composition of the overriding plate. The intersections of the megathrust with the accretionary prism, arc crust, metamorphic belt, and upper mantle down to the asthenosphere constitute important domain boundaries that shape the characteristics of the seismic cycle. The mechanical interactions between neighboring fault segments and the impact from the long-term viscoelastic flow strongly modulate the recurrence pattern of earthquakes and slow-slip events. Afterslip penetrates down-dip and up-dip into slow-slip regions, leading to accelerated slow-slip cycles at depth and long-lasting creep waves in the accretionary prism. The trench-ward migrating locking boundary near the bottom of the seismogenic zone progressively increases the size of long-term slow-slip events during the interseismic period. Fault dynamics is complex and potentially tsunami-genic in the accretionary region due to low friction, off-fault deformation, and coupling with the seismogenic zone.
topic Friction
Rheology
Subduction zones
url http://link.springer.com/article/10.1186/s40623-020-1145-0
work_keys_str_mv AT qibinshi structuralcontrolandsystemlevelbehavioroftheseismiccycleatthenankaitrough
AT sylvainbarbot structuralcontrolandsystemlevelbehavioroftheseismiccycleatthenankaitrough
AT shengjiwei structuralcontrolandsystemlevelbehavioroftheseismiccycleatthenankaitrough
AT paultapponnier structuralcontrolandsystemlevelbehavioroftheseismiccycleatthenankaitrough
AT takanorimatsuzawa structuralcontrolandsystemlevelbehavioroftheseismiccycleatthenankaitrough
AT bunichiroshibazaki structuralcontrolandsystemlevelbehavioroftheseismiccycleatthenankaitrough
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