Areas prone to slow slip events impede earthquake rupture propagation and promote afterslip

Rolandone, F.; Nocquet, Jean‐Mathieu; Mothes, Patricia; Jarrín, Paúl; Vallée, Martin; Cubas, Nadaya; Hernández, Stephen; Plain, M.; Vaca, Sandro; Font, Yvonne

doi:10.1126/sciadv.aao6596

Cited by 94 publications

(204 citation statements)

References 41 publications

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“…The postseismic observations of larger earthquakes were made by a range of researchers over a range of timescales, from days to years after the earthquakes, as listed in Table S3. The large‐event moment ratios come from 35 earthquakes numbered in Figure , from the 1: 2005 Chaman (Furuya & Satyabala, ), 2: 2008 Mogul, NV swarm (Bell et al, ), 3: 1998 San Juan Bautista (Taira et al, ), 4: 2007 Alum Rock, CA (Murray‐Moraleda & Simpson, ), 5: 2007 Ghazaband (Fattahi et al, ), 6: 2004 Parkfield (Freed, ; Langbein et al, ), 7: 2014 South Napa (Amoruso & Crescentini, ; Cheloni et al, ; Floyd et al, ), 8: 2009 L'Aquila (D'Agostino et al, ), 9: 2008 Nima‐Gaize, Tibet (Ryder et al, ), 10: 2000 Iceland (Jónsson, ), 11: 2003 San Simeon (Johanson & Bürgmann, ), 12: 2003 Zemmouri (Cetin et al, ; Mahsas et al, ), 13: 1989 Loma Prieta (Segall et al, ), 14: 1991 Racha, Georgia (Podgorski et al, ), 15: 1999 Hector Mine (Jacobs et al, ), 16: 2003 Altai (Barbot et al, ), 17: 2010 El Mayor‐Cucapah (Gonzalez‐Ortega et al, ), 18: 2011 Van (Dogan et al, ), 19: 1992 Landers (Savage & Svarc, ), 20: 1997 Manyi, Tibet (Ryder et al, ), 21: 2012 Nicoya (Hobbs et al, ; Malservisi et al, ), 22: 1994 Sanriku (Heki et al, ; Melbourne et al, ), 23: 2015 Gorkha (Sreejith et al, ), 24: 2001 Kokoxili, Tibet (Wen et al, ), 25: 1997 Kronotsky (Bürgmann et al, ), 26: 2016 Pedernales (Rolandone et al, ), 27: 2008 Wenchuan (Diao et al, ), 28: 1995 Jalisco (Melbourne et al, ), 29: 2003 Tokachi‐Oki (Miura et al, ), 30: 1995 Antofagasta (Melbourne et al, ; Pritchard & Simons, ), 31: 2015 Illapel (Shrivastava et al, ), 32: 2001 Peru (Melbourne et al, ), 33: 2005 Nias (Hsu et al, ), 34: 2010 Maule (Lin et al, ), and 35: 2004 Sumatra (Chlieh et al, ; Subarya et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…First, the varying postseismic moments could reflect fault properties. Smaller earthquakes may be more likely to occur on creeping sections of faults, perhaps on asperities surrounded by velocity‐strengthening fault sections that are more prone to large postseismic slip (e.g., Rolandone et al, ; Vaca et al, ). The postseismic moment estimates for M < 3.5 earthquakes all come from a single 20‐km‐wide fault segment near San Juan Bautista, CA, which could have particular properties (Hawthorne et al, ).…”

Section: Discussionmentioning

confidence: 99%

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Intermediate‐Magnitude Postseismic Slip Follows Intermediate‐Magnitude (M4 to 5) Earthquakes in California

Alwahedi

Hawthorne

2019

Geophysical Research Letters

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The magnitude of postseismic slip is useful for constraining physical models of fault slip. Here we examine the postseismic slip following intermediate‐magnitude (M 4 to 5) earthquakes by systematically analyzing data from borehole strainmeters in central and northern California. We assess the noise in the data and identify 11 earthquakes that generated interpretable strain records. We estimate the earthquakes' postseismic to coseismic moment ratios by comparing the coseismic strain changes with strain changes induced by afterslip in the following 1.5 days. The median estimated postseismic moment is 0.45 times the coseismic moment, with a 90% confidence interval between 0.25 and 0.60. This postseismic moment is slightly larger than typically observed following large (M > 6) earthquakes but smaller than observed following small (M2 to 4) earthquakes. The intermediate‐magnitude postseismic slip suggests a size dependence in the dynamics of earthquakes or in the properties of fault areas that surround earthquakes.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Intermediate‐Magnitude Postseismic Slip Follows Intermediate‐Magnitude (M4 to 5) Earthquakes in California

Alwahedi

Hawthorne

2019

Geophysical Research Letters

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“…Furthermore, we do not find any SSEs shallower than the five detected SSEs. Dixon et al () and Rolandone et al () suggested that shallower SSEs may reduce the tsunami potential along the shallow part of the plate interface because those SSEs release at least part of the accumulated slip deficit and may limit coseismic rupture propagation. These previous studies, together with the absence of shallow slow slip found in this study, may be consistent with the possibility of shallow historical tsunami earthquake (Nakamura, ) and may imply future tsunami earthquakes in the southern Ryukyu subduction zone.…”

Section: Discussionmentioning

confidence: 99%

Spatiotemporal Evolution of Recurrent Slow Slip Events Along the Southern Ryukyu Subduction Zone, Japan, From 2010 to 2013

et al. 2018

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Slow slip events (SSEs) with a moment magnitude of 6.6–6.7 occur at intervals of 5–9 months along the southern Ryukyu subduction zone in southwestern Japan. To obtain detailed image of these SSEs, this study applies a modified Network Inversion Filter to the Global Navigation Satellite System time series from March 2010 to February 2013 and estimates the spatiotemporal evolution of slow slip on the plate interface. Five SSEs are detected during this period. These events have similar cumulative slip distributions and are located near the northwestern coast of Iriomote Island at depths of 30–60 km, indicating that the SSEs recur in the same fault area. The analysis reveals that the spatiotemporal evolution of slip during the five SSEs varies from event to event. The notable feature is that three of the five SSEs nucleate rapidly and reach the maximum slip rate within several days, while the other two SSEs show much slower nucleation, lasting for 25–45 days prior to rapid acceleration of slip. Such variations in spatiotemporal evolution suggest temporal changes of fault properties such as fluid distribution and fault friction. Very low frequency earthquakes and low‐frequency earthquakes are activated during one of the five SSEs. The source area of the SSEs is complimentarily located in a deeper part of the very low frequency earthquakes and low‐frequency earthquake source areas, and a possible tsunami source region is located near the trench, indicating the depth dependence of the physical properties along the plate interface.

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“…SSEs have now been observed in a variety of tectonic settings, spanning timescales from seconds to years (Peng & Gomberg, 2010) and with equivalent geodetic moment magnitude from M ∼ 1 up to M ∼ 7.5 (e.g., Beroza & Ide, 2011;Ide et al, 2007). SSEs are sometimes accompanied by an increase in seismicity (Rolandone et al, 2018;Segall et al, 2006;Vallée et al, 2013) or by nonvolcanic tremors (e.g., Peng & Gomberg, 2010;Rogers & Dragert, 2003), and together represent an important mechanism of strain release in active regions. Aseismic slip also occurs as stress-driven afterslip in response to the stress change imparted by a coseismic stress drop (e.g., Marone et al, 1991).…”

Section: Introductionmentioning

confidence: 99%

“…Stress perturbations from a mainshock rupture can trigger spontaneous or delayed SSEs (over hours to months; e.g., Hayes et al, 2014;Hirose et al, 2012;Rolandone et al, 2018), which release stress that had built up during the previous inter-SSE interval (Bürgmann, 2018), and can also trigger transient creep (Lienkaemper et al, 1997;Wei et al, 2015) or modulate surface creep rate (Xu et al, 2018). In general, dynamic triggering of SSEs remains a rare phenomenon, and only a few cases are documented (Araki et al, 2017;Itaba & Ando, 2011;Wallace et al, 2017;Zigone et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Testing the Influence of Static and Dynamic Stress Perturbations On the Occurrence of a Shallow, Slow Slip Event in Eastern Taiwan

et al. 2019

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We report the first evidence for the detection of a slow slip event in the Longitudinal Valley, in eastern Taiwan. The slow event, which lasted about 3.5 days, has been detected by borehole strainmeters. It occurred at shallow depths (about 2 to 4 km), either on the Longitudinal Valley Fault or on the Central Range Fault. Here we investigate whether the event occurrence was influenced by transient and periodic stress perturbations, in particular by the June 2013 Mw 6.2 Nantou earthquake, which occurred about 60 km away and 6 days prior to the event. Modeled changes in Coulomb stress in the direction parallel to the geologic slip vector on the fault planes show negative static stress changes (approximately −1.5 to −1 kPa), while maximum dynamic stress changes generated by the surface waves are ranging from 5.5 to 14.5 kPa. We also observe that the slow event initiated during a maximum of Earth and ocean tidal Coulomb stress changes (about 0.8 to 1.5 kPa). Dynamic and static stress perturbations represent a few percents to tens of percents of the stress buildup through the slow rupture cycle. However, the absence of recurrent events during the 12 years of strain monitoring (2006 to 2018) prevents to estimate the recurrence interval of the slow event, which limits our ability to further interpret the link between the rupture and the perturbations. Finally, there is no large and unique load transient at the time of the initiation, therefore this single event may have likely occurred spontaneously.

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Areas prone to slow slip events impede earthquake rupture propagation and promote afterslip

Abstract: Frequent slow slip events and rapid postseismic slip reveal persistent aseismic fault areas delineating future seismic ruptures.

Cited by 94 publications

References 41 publications

Intermediate‐Magnitude Postseismic Slip Follows Intermediate‐Magnitude (M4 to 5) Earthquakes in California

Intermediate‐Magnitude Postseismic Slip Follows Intermediate‐Magnitude (M4 to 5) Earthquakes in California

Spatiotemporal Evolution of Recurrent Slow Slip Events Along the Southern Ryukyu Subduction Zone, Japan, From 2010 to 2013

Testing the Influence of Static and Dynamic Stress Perturbations On the Occurrence of a Shallow, Slow Slip Event in Eastern Taiwan

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