Complex and Diverse Rupture Processes of the 2018 Mw 8.2 and Mw 7.9 Tonga-Fiji Deep Earthquakes
Date: 4/26/2019
Time: 09:00 AM
Room: Cascade II
Deep earthquakes exhibit strong variabilities in their rupture and aftershock characteristics, yet their physical failure mechanisms remain elusive. The 2018 Mw 8.2 and Mw 7.9 Tonga-Fiji deep earthquakes, the two largest ever recorded in this subduction zone, occurred within days of each other. We investigate these events by performing waveform analysis, teleseismic P-wave back-projection, and aftershock relocation. Our results show that the Mw 8.2 earthquake ruptured fast (4.1 km/s) and excited frequency dependent seismic radiation, whereas the Mw~7.9 earthquake ruptured slowly (2.5 km/s). Both events lasted ~35 s. The Mw 8.2 earthquake initiated in highly seismogenic, cold core of the slab and likely ruptured into the surrounding warmer materials, whereas the Mw 7.9 earthquake likely ruptured through a dissipative process in a relatively aseismic region. The contrasts in earthquake kinematics and aftershock productivity argue for a combination of at least two primary mechanisms enabling rupture in the region.
Presenting Author: Wenyuan Fan
Authors
Wenyuan Fan wfan@fsu.edu Florida State University, Tallahassee, Florida, United States Presenting Author
Corresponding Author
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Songqiao Wei swei@msu.edu Michigan State University, East Lansing, Michigan, United States |
Dongdong Tian tiandong@msu.edu Michigan State University, East Lansing, Michigan, United States |
Jeffrey J McGuire jmcguire@whoi.edu Woods Hole Oceanographic Institution, Woods Hole, Massachusetts, United States |
Douglas A Wiens doug@wustl.edu Washington University in St. Louis, St. Louis, Missouri, United States |
Complex and Diverse Rupture Processes of the 2018 Mw 8.2 and Mw 7.9 Tonga-Fiji Deep Earthquakes
Category
Large Intraslab Earthquakes