Ground Motions from the 7 and 19 September 2017 Tehuantepec and Puebla‐Morelos, Mexico, Earthquakes

Deep sedimentary basins amplify long‐period shaking from seismic waves, increasing the seismic hazard for cities sited on such basins. We perform 3‐D simulations of point source earthquakes distributed around the Seattle and Tacoma basins in Washington State to examine the dependence of basin amplification on source azimuth, depth, and earthquake type. For periods between 1 and 10 s, the pattern of amplification is spatially heterogeneous and differs considerably with the source‐to‐site azimuth. For close‐in earthquakes, the greatest basin amplification occurs toward the farside of the basin and ground motions from crustal earthquakes experience greater amplification than those from more vertically incident, deeper intraplate earthquakes. Love and Rayleigh waves form similar spatial patterns for a given source location, although the magnitude of amplification varies. The source dependence of basin amplification is an important factor for seismic hazard assessment, in both the Seattle and Tacoma basins, and by extension for deep sedimentary basins worldwide.

Section: Introductionmentioning

confidence: 99%

Source‐Dependent Amplification of Earthquake Ground Motions in Deep Sedimentary Basins

Wirth

Vidale

Frankel

et al. 2019

“…Strong motions generated by the event (Sahakian et al, 2018) were felt as far away as Mexico city (900 km from the epicenter), and there was widespread damage and loss of life in the epicentral region. Strong motions generated by the event (Sahakian et al, 2018) were felt as far away as Mexico city (900 km from the epicenter), and there was widespread damage and loss of life in the epicentral region.…”

Section: The Tehuantepec Earthquake and Tsunamimentioning

confidence: 99%

“…The earthquake was significant for the region. Strong motions generated by the event (Sahakian et al, 2018) were felt as far away as Mexico city (900 km from the epicenter), and there was widespread damage and loss of life in the epicentral region. Additionally, the earthquake produce a moderate tsunami.…”

Section: The Tehuantepec Earthquake and Tsunamimentioning

confidence: 99%

Long‐Lived Tsunami Edge Waves and Shelf Resonance From the M8.2 Tehuantepec Earthquake

Melgar

Ruiz‐Angulo

2018

Self Cite

The 8 September 2017 M8.2 Tehuantepec, Mexico, earthquake ruptured an ~150‐km‐long high‐angle normal fault below the subduction zone megathrust. A tsunami was generated by the event with surveyed runup as large as 3 m. Tide gauges in the region show a remarkably long duration of the tsunami with oscillations within the very wide and shallow Tehuantepec shelf lasting as long as 3 days. Here we produce a model of the tsunami and validate it by comparing it to the tsunami survey and to the time and frequency domain features of regional tide gauges. We analyze the model results and show that the long‐lived oscillations are a result of wholesale resonance of the shelf as well as very efficient trapping of edge waves at the shore. These resonant features are the result of the Tehuantepec shelf morphology and illuminate a previously unidentified tsunami hazard for the region.

“…This earthquake is ranked as the strongest intraplate event ever recorded in Mexico with a moment magnitude of M 8.2, and the third largest intraplate event known globally (Wiens et al, 1998;Yue et al, 2012). Eleven days after the event, another intraslab earthquake ruptured near Mexico City (e.g., Melgar, Pérez-Campos, et al, 2018) causing widespread damage in Mexico's capital, where nearly~300 people died and~45 building collapsed due to basin amplification (Çelebi et al, 2018;Cruz-Atienza et al, 2016;Galvis et al, 2017;Sahakian et al, 2018;Singh et al, 2018). The Mexican earthquake early warning system delivered an alert to major cities in central Mexico within a few seconds after the earthquake, sirens in Mexico City went off 92 s before the arrival of the surface waves which arrived near midnight 7 September 2017 local time (Suárez et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…The Mexican earthquake early warning system delivered an alert to major cities in central Mexico within a few seconds after the earthquake, sirens in Mexico City went off 92 s before the arrival of the surface waves which arrived near midnight 7 September 2017 local time (Suárez et al, 2018). Eleven days after the event, another intraslab earthquake ruptured near Mexico City (e.g., Melgar, Pérez-Campos, et al, 2018) causing widespread damage in Mexico's capital, where nearly~300 people died and~45 building collapsed due to basin amplification (Çelebi et al, 2018;Cruz-Atienza et al, 2016;Galvis et al, 2017;Sahakian et al, 2018;Singh et al, 2018). This event coincidentally occurred on the 32nd anniversary of the great 1985 M 8.1 Michoacan earthquake, only 2 hr after the annual national earthquake drill.…”

Section: Introductionmentioning

confidence: 99%

Nucleation and Kinematic Rupture of the 2017 Mw 8.2 Tehuantepec Earthquake

Meng

Huang

Xie

et al. 2019

Integrated observations from the 2017 Mw 8.2 Tehuantepec, Mexico, earthquake probe one of the largest normal‐faulting events inside a subducting slab. In this study, we utilize a template matching approach to detect possible missing earthquakes within a 2‐month period before the mainshock. The seismicity rate shows an abrupt increase in the last day around the mainshock hypocenter. The large distance between most of the foreshocks and the mainshock is not consistent with static stress triggering but suggests alternative mechanisms such as delayed dynamic triggering or aseismic transients. Back‐projection using the USArray network reveals that the rupture propagated northwestward unilaterally at a speed of 3.6 km/s and terminated north of the Tehuantepec Ridge. Towards the end of the rupture, a wide step‐over occurred onto an adjacent fault parallel to the main fault plane. The mainshock is likely a reactivation of subducted outer‐rise faults, supported by the similarity of fault‐strike angles. The surprisingly large magnitude is consistent with exceedingly large dimensions of outer‐rise faulting in this segment of the central Mexican trench.