TY - JOUR
T1 - A seismogeodetic amphibious network in the Guerrero Seismic Gap, Mexico
AU - Cruz-Atienza, Víctor M.
AU - Ito, Yoshihiro
AU - Kostoglodov, Vladimir
AU - Hjörleifsdóttir, Vala
AU - Iglesias, Arturo
AU - Tago, Josué
AU - Calò, Marco
AU - Real, Jorge
AU - Husker, Allen
AU - Ide, Satoshi
AU - Nishimura, Takuya
AU - Shinohara, Masanao
AU - Mortera-Gutierrez, Carlos
AU - García, Soliman
AU - Kido, Motoyuki
N1 - Funding Information:
Physics-based earthquake and tsunami scenarios in the GGap constrained by state-of-the-art observations, both onshore and offshore, are thus urgently needed for disasters mitigation caused by future megathrust earthquakes in the Pacific coast of Mexico. To achieve this goal, we installed in 2017 a seismogeodetic amphibious network in the region. The network is composed of seismic (Fig. 2a) and geodetic (Fig. 2b) instruments installed offshore and onshore as a part of the 2016–2021 international collaborative research project Hazard Assessment of Large Earthquakes and Tsunamis in the Mexican Pacific Coast for Disaster Mitigation funded by the Japanese and Mexican governments through different agencies and institutions. Results from this collaboration should significantly contribute to risk mitigation in Mexico and to the identification of similarities (and differences) between the subduction zones of Japan and Mexico, leading to a better understanding of the physical mechanisms of megathrust earthquakes and tsunamis in subduction margins.
Funding Information:
The seismogeodetic amphibious network and the associated binational research project is being funded by (1) the Japanese government through the program Science and Technology Research Partnership for Sustainable Development (SATREPS) via the Japan International Cooperation Agency (JICA) and the Japan Science and Technology Agency (JST) and through the Universities of Kyoto (U of K) and Tokyo with Grant Number 15543611 and MEXT KAKANHI Number 16H02219, respectively, and (2) the Mexican government through the Universidad Nacional Autónoma de México (UNAM) with PAPIIT Grant Numbers IN113814, IN111316, IG100617, IN115613, and IN107116, its Coordi-nación de la Investigación Científica (CTIC and COPO) with research vessel time, its central administration through importation fees, its Instituto de Ciencias del Mar y Limno-logía - Unidad Mazatlán, and its Servicio Sismológico Nacional (SSN); the Consejo Nacional de Ciencia y Tecnología (CONACyT) through Grant Numbers 268119, 273832, and 255308; the Mexican Ministry of Foreign Affairs through the Agencia Mexicana de Cooperación Internacional para el Desarrollo (AMEXCID); and the Centro Nacional de Preven-ción de Desastres (CENAPRED). For their support and collaboration in the acquisition of the GPS-A measurements, the authors especially thank Sharadha Sathiakumar, Grace Chia, Sylvain Bar-bot, and David Chadwell. The authors specially thank the outstanding work of Arika Nagata, Kumiko Ogura, Vanessa Ayala, Liliana Córdova, José Luis Carballo, Lorena García, José Antonio Santiago, Ekaterina Kazachkina, and Sara Ivonne Franco, as well as all the administrative staffs from the U of K, UNAM, JICA, JST, AMEXCID, and CONACyT that made all this possible. The authors also especially thank the Secretaría de Protección Civil del Estado de Guerrero and the Secretaría de Marina (SEMAR) for their unconditional support.
Publisher Copyright:
© 2018 Seismological Society of America. All rights reserved.
PY - 2018/7/1
Y1 - 2018/7/1
N2 - The historical record of large subduction earthquakes in Guerrero, Mexico, reveals the existence of an 230-km length segment below the coast where no major rupture has occurred in the past 60 years. Reliable quantification of the hazard associated with such a seismic gap is urgently needed for risk mitigation purposes by means of state-of-the-art observations and modeling. In this article, we introduce and quantitatively assess the first seismogeodetic amphibious network deployed in Mexican and Central American soils that will provide the opportunity to achieve this goal in the near future. Deployed in 2017, the network is the result of a collaborative effort between Mexican and Japanese scientists. It consists of 15 onshore broadband and 7 ocean-bottom seismometers, 33 Global Positioning System (GPS) stations, 7 ocean-bottom pressure gauges, and 2 GPSacoustic sites,most of them installed within the Guerrero seismic gap. Initial data from the network revealed the occurrence of a 6-month-long slow-slip event in Guerrero, starting in May and ending in October 2017. To illustrate the performance of the various instruments, we also present the first ocean-bottom pressure and GPS-acoustic measurements in Mexico; the latter was obtained by means of an autonomousWave Glider vehicle. The ground motion of the devastating 19 September 2017 Mw 7.1 earthquake in central Mexico is presented as well. Nominal resolution of the seismogeodetic network is estimated through different synthetic inversion tests for tomographic imaging and the seismic coupling (or slow-slip) determination on the plate interface. The tests show that combined onshore and offshore instruments should lead to unprecedented results regarding the seismic potential (i.e., interface coupling) of the seismic gap and the Earth structure from the Middle America trench up to 70-km depth across the Guerrero state.
AB - The historical record of large subduction earthquakes in Guerrero, Mexico, reveals the existence of an 230-km length segment below the coast where no major rupture has occurred in the past 60 years. Reliable quantification of the hazard associated with such a seismic gap is urgently needed for risk mitigation purposes by means of state-of-the-art observations and modeling. In this article, we introduce and quantitatively assess the first seismogeodetic amphibious network deployed in Mexican and Central American soils that will provide the opportunity to achieve this goal in the near future. Deployed in 2017, the network is the result of a collaborative effort between Mexican and Japanese scientists. It consists of 15 onshore broadband and 7 ocean-bottom seismometers, 33 Global Positioning System (GPS) stations, 7 ocean-bottom pressure gauges, and 2 GPSacoustic sites,most of them installed within the Guerrero seismic gap. Initial data from the network revealed the occurrence of a 6-month-long slow-slip event in Guerrero, starting in May and ending in October 2017. To illustrate the performance of the various instruments, we also present the first ocean-bottom pressure and GPS-acoustic measurements in Mexico; the latter was obtained by means of an autonomousWave Glider vehicle. The ground motion of the devastating 19 September 2017 Mw 7.1 earthquake in central Mexico is presented as well. Nominal resolution of the seismogeodetic network is estimated through different synthetic inversion tests for tomographic imaging and the seismic coupling (or slow-slip) determination on the plate interface. The tests show that combined onshore and offshore instruments should lead to unprecedented results regarding the seismic potential (i.e., interface coupling) of the seismic gap and the Earth structure from the Middle America trench up to 70-km depth across the Guerrero state.
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U2 - 10.1785/0220170173
DO - 10.1785/0220170173
M3 - Article
AN - SCOPUS:85049775941
SN - 0895-0695
VL - 89
SP - 1435
EP - 1449
JO - Seismological Research Letters
JF - Seismological Research Letters
IS - 4
ER -