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Paleoearthquake Investigation along the Chenghai Fault Zone since ∼500 ka, Southeast Margin of the Tibetan Plateau
Author(s) -
YANG Shuaibin,
QIAO Yansong,
WU Zhonghai,
ZHANG Xujiao,
QI Lin,
HE Zexin,
LIANG Ying
Publication year - 2021
Publication title -
acta geologica sinica ‐ english edition
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.444
H-Index - 61
eISSN - 1755-6724
pISSN - 1000-9515
DOI - 10.1111/1755-6724.14513
Subject(s) - geology , seismology , active fault , tectonics , plateau (mathematics) , mathematical analysis , mathematics
Abstract The Chenghai fault zone is located in the Sichuan–Yunnan rhombus block, which is surrounded by the Honghe River, Xianshuihe–Xiaojiang, and Jinsha River fault zones. As a mid‐continental active fault, it is one of the most important seismogenic fractures in the southeast margin of the Tibetan Plateau. Geological seismic study is an important supplement to the historical seismic record; therefore, identification of paleoearthquake events in this region is of great significance to reveal the pattern and mechanism of earthquake development. In this study, detailed investigation has been carried out on the earthquake traces that formed in the Quaternary sediments in the Jinsha River section of the Chenghai fault zone, and samples for dating chronology testing were also collected. Many paleoearthquake traces were discovered in the field, including earthquake fissions, dammed lake sediments and landslides, earthquake‐generated rock falls, seismic faults, and sand liquefaction veins. The collected samples were tested using optically stimulated luminescence, electron‐spin resonance, and U‐series methods. A total of 68 chronological samples were dated, combined with the results of field investigations, and 10 large paleoearthquake events were discovered in this region since 500 ka, which are at approximately 450, 400, 345, 300, 250, 190, 155, 105, 75, and 25 ka. Ten tectonic activity periods that produced multiple paleoearthquake events were identified since 500 ka. This study identifies paleoearthquake events in longer scales, larger spaces, and more extensive sediments, which provides new perspectives and new ideas for paleoearthquake research.