The 2016 Kumamoto <i>M<sub>w</sub></i> = 7.0 Earthquake: A Significant Event in a Fault–Volcano System

Yue, Han; Ross, Zachary E.; Liang, Cunren; Michel, Sylvain; Fattahi, H.; Fielding, E. J.; Moore, A. W.; Liu, Zhen; Jia, Bo

doi:10.1002/2017jb014525

Cited by 72 publications

(103 citation statements)

References 74 publications

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“…At the northeast end of rupture fault, there is a high productivity asperity where the coseismic rupture terminates and a gap of ∼8 km length, with low productivity values, in between. This gap is consistent with the 10‐km‐long gap of aftershocks reported in Yue et al () who attribute this phenomenon to partial melting in this volcanic region.…”

Section: Resultssupporting

confidence: 92%

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Modeling and Forecasting Aftershocks Can Be Improved by Incorporating Rupture Geometry in the ETAS Model

Guo

Zhuang

Ogata

2019

Geophysical Research Letters

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We implemented an extended version of the space‐time Epidemic‐Type Aftershock Sequence (ETAS) model, which simultaneously incorporates earthquake focal depths and rupture geometries of large earthquakes, and applied it to the 2016 Kumamoto earthquake sequence. Results show that the new model corrects the estimation biases of model parameters in the point source ETAS model. The reconstructed patterns of productivity density of aftershocks, along the mainshock rupture plane, form complementary patterns for coseismic slip in space and show significant spatiotemporal migrations. Large aftershocks tend to nucleate at the edges of high productivity density areas. The decay of direct aftershocks near the mainshock rupture is consistent with static stress changes caused by the mainshock. The forecasting capability of the ETAS model can be enhanced by considering the rupture geometries of mainshocks, especially for forecasting aftershocks in the first 1–2 days. In the simulation test, the incorporation of focal depths improves the forecasting resolution.

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Section: Resultssupporting

confidence: 92%

“…(b1-c3) Comparison between aftershock productivity distribution and coseismic slip distribution. (b1-b3) Interpolated productivity distributions on the mainshock fault planes from results ofYagi et al (2016),Asano and Iwata (2016), andYue et al (2017). (c1-c3) Slip distributions from the three models.…”

mentioning

confidence: 99%

Modeling and Forecasting Aftershocks Can Be Improved by Incorporating Rupture Geometry in the ETAS Model

Guo

Zhuang

Ogata

2019

Geophysical Research Letters

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“…From this sense, the Huya and Minjiang are splay faults associated with the Tazang fault, which is a direct extension of the East Kunlun fault. Similar splay faults were often resolved as hosting the initial rupture of great earthquakes such as the 2001 Kokoxili earthquake (Klinger et al, 2005) or foreshocks such as the 2016 Kumamoto earthquake (Yue et al, 2017). Therefore, the occurrence of the Jiuzhaigou earthquake calls for attention for the future seismic hazard on the Tazang or the East Kunlun fault.…”

Section: Rupture On An Obtuse Branchmentioning

confidence: 99%

The 2017 Jiuzhaigou Earthquake: A Complicated Event Occurred in a Young Fault System

Sun

Yue

Shen

et al. 2018

Geophysical Research Letters

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The Minshan Uplift Zone (MUZ) is located at the eastern margin of the Tibetan Plateau, which is the junction of three tectonic terranes. The observed discrepancy between a high uplifting and low shortening rate over the MUZ is attributed to the intrusion of a viscous lower crust. In the last 50 years, several significant earthquakes occurred at the boundaries of the MUZ, that is, the Huya and Mingjiang faults. On 8 August 2017, the Jiuzhaigou earthquake (Mw 6.5) occurred on the northern extension of the Huya fault. We adopt a joint inversion of the interferometric synthetic aperture radar and teleseismic body wave data to investigate the rupture process of this event. The obtained slip model is dominated by left‐lateral strike slips on a subvertical fault presenting significant shallow slip deficit. The rupture initiation is composed of both thrust and strike‐slip mechanisms producing a non‐double‐couple solution. We also resolve a secondary fault branch forming an obtuse angle with the main fault plane at its northern end. These phenomena indicate that the northern Huya fault is a young (less mature) fault system. Focal mechanisms of the regional earthquakes demonstrate that the northern and southern Huya faults present different combinations of strike‐slip and reversed motion. We attribute such discrepancy to the lateral extension of the viscous lower crust, which appears to extrude to the east beyond the northern Huya fault, in comparison with that confined under the MUZ near the southern Huya fault. This conceptual model is also supported by geomorphological and magnetotelluric observations.

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“…Many studies have demonstrated that fluids and arc magma exist under the Aso active volcano near the Kumamoto source zone: for example, a high‐temperature (over ~500 °C) anomaly at ~3‐km depth beneath the Aso caldera (Okubo & Shibuya, ), a prominent low‐velocity anomaly indicating a magma chamber (H. Wang et al, ; Xia et al, ; Yu et al, ; Zhao et al, ), a broad low‐viscosity anomaly in the lower crust (Moore et al, ), a large velocity reduction caused by pressurized volcanic fluids (Nimiya et al, ), and volcanic rocks containing components of slab‐derived fluids (Kita et al, ). Coulomb stress changes indicate that the high‐temperature and widespread fluids around the Aso volcano also stopped the rupture of the Kumamoto mainshock (Yue et al, ; Zhang et al, ). It is generally considered that arc magma and fluids can affect the generation of large crustal earthquakes in Japan (e.g., Liu & Zhao, ; Tong et al, ; Zhao, ; Zhao et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…Journal of Geophysical Research: Solid Earth high-temperature and widespread fluids around the Aso volcano also stopped the rupture of the Kumamoto mainshock (Yue et al, 2017;Zhang et al, 2018). It is generally considered that arc magma and fluids can affect the generation of large crustal earthquakes in Japan (e.g., Liu & Zhao, 2015;Tong et al, 2012;Zhao, 2015;Zhao et al, 1996).…”

Section: 1029/2018jb017079mentioning

confidence: 99%

Stress Field in the 2016 Kumamoto Earthquake (M 7.3) Area

Zhao

et al. 2019

JGR Solid Earth

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We used 1‐D and 3‐D velocity models to determine focal mechanism solutions (FMSs) of 349 crustal earthquakes (M 2.7–7.3) and stress tensors in the source area of the 2016 Kumamoto earthquake (M 7.3) that occurred on the Futagawa‐Hinagu fault zone in Kyushu, Southwest Japan. There are some differences in the FMSs determined with the 1‐D and 3‐D velocity models. The use of the 3‐D velocity model leads to better results of stress tensors, which are determined by inverting the FMSs. The orientation of the minimum stress (σ3) axis is more accurately determined, which trends NNW‐SSE to N‐S nearly horizontally. In contrast, the axes of the maximum and intermediate stresses (σ1 and σ2) trend WSW‐ENE to E‐W with wide ranges. Significant spatiotemporal variations of the stress field are revealed in the Kumamoto source zone, indicating a small magnitude of deviatoric stress. The friction coefficient of the faults is estimated to be relatively small (~0.4), indicating that the seismogenic faults in central Kyushu are weak. The fault weakening may be caused by fluids beneath the source area and arc magma under the nearby Aso active volcano.

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The 2016 Kumamoto M_w = 7.0 Earthquake: A Significant Event in a Fault–Volcano System

Cited by 72 publications

References 74 publications

Modeling and Forecasting Aftershocks Can Be Improved by Incorporating Rupture Geometry in the ETAS Model

Modeling and Forecasting Aftershocks Can Be Improved by Incorporating Rupture Geometry in the ETAS Model

The 2017 Jiuzhaigou Earthquake: A Complicated Event Occurred in a Young Fault System

Stress Field in the 2016 Kumamoto Earthquake (M 7.3) Area

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The 2016 Kumamoto Mw = 7.0 Earthquake: A Significant Event in a Fault–Volcano System

Cited by 72 publications

References 74 publications

Modeling and Forecasting Aftershocks Can Be Improved by Incorporating Rupture Geometry in the ETAS Model

Modeling and Forecasting Aftershocks Can Be Improved by Incorporating Rupture Geometry in the ETAS Model

The 2017 Jiuzhaigou Earthquake: A Complicated Event Occurred in a Young Fault System

Stress Field in the 2016 Kumamoto Earthquake (M 7.3) Area

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The 2016 Kumamoto M_w = 7.0 Earthquake: A Significant Event in a Fault–Volcano System