Ridge subduction and afterslip control aftershock distribution of the 2016 Mw 7.8 Ecuador earthquake

Agurto‐Detzel, Hans; Font, Yvonne; Charvis, Philippe; Régnier, Marc; Rietbrock, Andreas; Ambrois, David; Paulatto, M.; Alvarado, Alexandra; Beck, S. L.; Courboulex, Françoise; Barros, Louis De; Deschamps, A.; Hernandez, M‐J.; Hernández, Stephen; Hoskins, Mariah; León-Ríos, Sergio; Lynner, Colton; Meltzer, A.; Mercerat, Diego; Michaud, François; Nocquet, J.; Rolandone, F.; Ruiz, Mario; Soto‐Cordero, L.

doi:10.1016/j.epsl.2019.05.029

Cited by 29 publications

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“…A uniform earthquake catalog produced for seismic hazard assessment in Ecuador provides a basis for placing the Pedernales seismic sequence in the context of instrumental and historic seismicity from 1587 to 2009 (Beauval et al, ; Yepes et al, ). Similar patterns of focused clusters of seismicity are observed in both the background (interseismic) seismicity and postseismic Pedernales sequence (Figures a and b; Meltzer et al, , Agurto‐Detzel et al, ). The extent to which seismicity is more focused or diffuse is in part related to station density recording the postseismic sequence and in part due to the presence or absence of earthquake swarms during the period of observation (Figure ).…”

Section: Discussionsupporting

confidence: 68%

“…Earthquakes, Aseismic Slip, and Structure 5.4.1. Relationship to Interseismic Seismicity and Historical Earthquakes Seismicity in the Pedernales sequence matches patterns observed during the interseismic phase of the earthquake cycle, as well as maximum moment release and aftershock patterns of historic earthquakes (Figure 14; Rolandone et al, 2018Agurto-Detzel et al, 2019;León-Ríos et al, 2019). A uniform earthquake catalog produced for seismic hazard assessment in Ecuador provides a basis for placing the Pedernales seismic sequence in the context of instrumental and historic seismicity from 1587 to 2009 (Beauval et al, 2013;Yepes et al, 2016).…”

Section: The Pedernales Sequence: Relationship To Interseismic Seismimentioning

confidence: 65%

“…The Pedernales seismic sequence is dominated by pronounced spatial clustering and a striking downdip limit in seismic activity. Most of the events locate outside the rupture area of the main shock (Figure ; Meltzer et al, ; Agurto‐Detzel et al, ; León‐Ríos et al, ). Three apparent bands of seismicity run perpendicular to the strike of the trench: the Jama band updip from the southern end of the rupture, the Cojimies‐Atacames Seamount band approximately coincident with the northern end of the rupture, and the Galera band approximately 20 km north of the rupture (Figure ).…”

Section: Discussionmentioning

confidence: 99%

“…The relationship between interseismic coupling and seismicity varies along strike (Figure 14c; Chlieh et al, 2014;Nocquet et al, 2017;Rolandone et al, 2018;Agurto-Detzel et al, 2019). The Pedernales earthquake ruptured a moderately to highly coupled portion of the subduction zone.…”

Section: /2019jb018001mentioning

confidence: 99%

“…The seismicity clusters at Manta-Puerto Lopez, Jama, and along the Atacames Seamount chain correlate with seafloor topography on the subducting Carnegie Ridge and Atacames Seamounts. These topographic features have been imaged by active source seismic (Collot et al, 2017;Marcaillou et al, 2016) and appear in residual bathymetry (Bassett & Watts, 2015;Agurto-Detzel et al, 2019. ) The composite clusters at Galera and northeast of the Pedernales rupture also correlate with residual bathymetry and gravity anomalies (see Figure 9; Bassett & Watts, 2015), suggesting that focused seismicity in these areas may be controlled by structure and/or deformation (imbricate faults) in the downgoing plate (Angiboust et al, 2014;Menant et al, 2018).…”

Section: Relationship To Structure-bathymetry Topography Accreted Tmentioning

confidence: 99%

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Structural Control on Megathrust Rupture and Slip Behavior: Insights From the 2016 Mw 7.8 Pedernales Ecuador Earthquake

et al. 2020

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The heterogeneous seafloor topography of the Nazca Plate as it enters the Ecuador subduction zone provides an opportunity to document the influence of seafloor roughness on slip behavior and megathrust rupture. The 2016 Mw 7.8 Pedernales Ecuador earthquake was followed by a rich and active postseismic sequence. An internationally coordinated rapid response effort installed a temporary seismic network to densify coastal stations of the permanent Ecuadorian national seismic network. A combination of 82 onshore short and intermediate period and broadband seismic stations and six ocean bottom seismometers recorded the postseismic Pedernales sequence for over a year after the mainshock. A robust earthquake catalog combined with calibrated relocations for a subset of magnitude ≥4 earthquakes shows pronounced spatial and temporal clustering. A range of slip behavior accommodates postseismic deformation including earthquakes, slow slip events, and earthquake swarms. Models of plate coupling and the consistency of earthquake clustering and slip behavior through multiple seismic cycles reveal a segmented subduction zone primarily controlled by subducted seafloor topography, accreted terranes, and inherited structure. The 2016 Pedernales mainshock triggered moderate to strong earthquakes (5 ≤ M ≤ 7) and earthquake swarms north of the mainshock rupture close to the epicenter of the 1906 Mw 8.8 earthquake and in the segment of the subduction zone that ruptured in 1958 in a Mw 7.7 earthquake.

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Section: Discussionsupporting

confidence: 68%

Section: The Pedernales Sequence: Relationship To Interseismic Seismimentioning

confidence: 65%

Section: Discussionmentioning

confidence: 99%

Section: /2019jb018001mentioning

confidence: 99%

Section: Relationship To Structure-bathymetry Topography Accreted Tmentioning

confidence: 99%

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Structural Control on Megathrust Rupture and Slip Behavior: Insights From the 2016 Mw 7.8 Pedernales Ecuador Earthquake

et al. 2020

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3D local earthquake tomography of the Ecuadorian margin in the source area of the 2016 Mw 7.8 Pedernales earthquake

León-Ríos

Bie

Agurto‐Detzel

et al. 2020

Preprint

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models were calculated using local earthquake tomography in the region affected by the 2016 Pedernales, Ecuador earthquake • Tomographic images highlight the heterogeneities of the margin affected by seamounts and ridges comprising the oceanic crust • Carnegie Ridge seems the main feature controlling the seismic activity and the offshore extent of large megathrust earthquakes in the region Supporting Information:

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Imaging rapid early afterslip of the 2016 Pedernales earthquake, Ecuador

Tsang

Vergnolle

Twardzik

et al. 2019

Earth and Planetary Science Letters

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High-Rate (HR) GPS time series following the 2016 M w 7.8 Pedernales earthquake suggest significant postseismic deformation occurring in the early postseismic period (i.e. first few hours after the earthquake) that is not captured in daily GPS time series. To understand the characteristics of early postseismic deformation, and its relationship with the mainshock rupture area, aftershocks and longer-term postseismic deformation, we estimate the spatiotemporal distribution of early afterslip with HR-GPS time series that span ~ 2.5 minutes to 72 hours after the earthquake, and compare with afterslip models estimated with daily GPS time series spanning a similar postseismic time period and up to 30 days after the earthquake. Our inversion technique enables us to image the nucleation of afterslip in the initial hours after the earthquake, bringing us closer to the transition between the coseismic and postseismic phases. The spatial signature of early afterslip in the region updip of the mainshock rupture area is consistent with longer-term afterslip that occurs in the 30-day postseismic period, indicating that afterslip nucleated updip of and adjacent to peak coseismic slip asperities, in two localized areas, and subsequently continued to grow in amplitude with time in these specific areas. A striking difference, however, is that inversion of the 72-hour HR-GPS time series suggests early afterslip within the mainshock rupture area, but which may have been short-lived. More interestingly, we find that postseismic slip starts immediately after the earthquake at a rapid rate. Indeed, we find that early afterslip represents a significant contribution to the postseismic geodetic moment-afterslip in the first 72 hours is ~60 % greater than that estimated with daily GPS time series that span the first three post-earthquake daily GPS positions (i.e. covering the same time window). The results of our study demonstrate that imaging the spatio-temporal evolution of afterslip using subdaily GPS time series is important for evaluating postseismic slip 3 | P a g e budgets, and provides additional insights into the postseismic slip behaviour of faults.

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Ridge subduction and afterslip control aftershock distribution of the 2016 Mw 7.8 Ecuador earthquake

Cited by 29 publications

References 48 publications

Structural Control on Megathrust Rupture and Slip Behavior: Insights From the 2016 Mw 7.8 Pedernales Ecuador Earthquake

Structural Control on Megathrust Rupture and Slip Behavior: Insights From the 2016 Mw 7.8 Pedernales Ecuador Earthquake

3D local earthquake tomography of the Ecuadorian margin in the source area of the 2016 Mw 7.8 Pedernales earthquake

Imaging rapid early afterslip of the 2016 Pedernales earthquake, Ecuador

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