FOCAL MECHANISM AND TSUNAMI NUMERICAL SIMULATION OF THE NOVEMBER 14, 2019 MOLUCCA SEA MW7.1 EARTHQUAKE

doi:10.3969/j.issn.0253-4967.2020.06.010

Abstract

Abstract: A strong earthquake with magnitude M_W=7.1 occurred in the area of Molucca Sea, Indonesia on November 14, 2019(Coordinated Universal Time, UTC), and then generated a small-scale local tsunami. In order to better understand the earthquake source characteristics and seismogenic structure, as well as to assess the hazard of tsunami caused by earthquake, this paper mainly focuses on the regional tectonic background, the focal mechanism, and tsunami numerical simulation for the Molucca Sea M_W7.1 earthquake. The broadband seismic waveforms from IRIS Data Management Center are used to estimate the moment tensor solution of this earthquake by W phase method. The result shows that the Molucca Sea earthquake occurred at a shallow depth on a high dip-angle, right-lateral reverse fault, the aftershocks were distributed along the SSW-NNE direction and concentrated near the main shock. These results indicate the Molucca Sea earthquake with characteristic of compressional rupture occurred in the complex plate boundary region of eastern Indonesia, which is dominated mostly by the collision interaction of the Halmahera slab and the Sangihe slab in the east and west sides of Molucca Sea under control of current regional stress field. The coseismic displacements of Molucca Sea M_W7.1 earthquake calculated using Okada's model of rectangular dislocation in a uniform elastic half-space show that the Molucca Sea earthquake generated vertical coseismic deformation with a maximum uplift of 0.15m when the rupture occurred along the high dip-angle reverse fault. The synthetic tsunami waveforms are provided by COMCOT tsunami modelling package solving the nonlinear shallow water wave equations based on the determined fault geometry from W phase inversion. These studies indicate the vertical coseismic deformation resulting in the sudden uplift of water volume above the earthquake source, and finally inducing a small-scale local tsunami. The energy of tsunami mainly propagates to both side of the fault, and part of energy propagates to Sula Islands of Indonesia along the fault dislocation direction; and compared with the first cycle of tsunami records observed by tide gauges deployed along the coastal line of earthquake source region, the observed tsunami head wave fits well with the synthetic wave, both are consistent in amplitude and tsunami arrival time, but the follow-up waveforms are quite different. The numerical simulation of tsunami shows that, in combination with the fault geometry parameters obtained by W phase fast inversion, the tsunami numerical model can be used for tsunami early warning, and it provides sufficient accuracy for forecasting tsunami wave height, thus, having great practical significance for understanding the propagation process and disaster distribution of tsunami.

Key words: Molucca Sea earthquake, tsunami, arc-arc collision, focal mechanism, numerical simulation

摘要： 2019年11月14日16时17分(UTC), 印尼马鲁古附近海域发生了M_W7.1地震, 并引发小规模海啸。为深入理解和认识该地震的震源参数和发震构造特征, 评估其引发海啸的危险性, 文中初步分析了该地震的区域构造背景、震源机制以及海啸数值模拟等内容。 W震相快速矩张量解反演结果表明马鲁古海地震是一次浅源、以高倾角右旋斜向逆冲为主的地震事件, 余震呈SSW-NNE向带状分布, 推测此次地震是在马鲁古海东、西两侧哈马黑拉弧-桑义赫弧碰撞所产生的区域应力场的作用下发生的以挤压破裂为主的地震事件。海啸的数值模拟结果表明, 在高倾角发震断层近垂直倾滑的逆冲过程中, 海底地形产生了同震垂直位移, 使得震源上方的水体突然抬升, 从而产生了小规模的局地海啸; 震源周边大部分潮位站记录的海啸首波理论波形和观测波形的到达时间和波形幅度都较为一致, 说明结合W震相反演所得的地震断层面的几何参数能够用于海啸早期预警, 可有效地预测海啸地震产生的海啸波高, 并对于认识海啸成灾过程及灾害分布具有重要的现实意义。

关键词: 马鲁古海地震, 海啸, 弧-弧碰撞, 震源机制, 数值模拟

CLC Number:

P315.2

XU Zhi-guo, WANG Jun-cheng, WANG Zong-chen, LIANG Shan-shan, SHI Jian-yu. FOCAL MECHANISM AND TSUNAMI NUMERICAL SIMULATION OF THE NOVEMBER 14, 2019 MOLUCCA SEA M_W7.1 EARTHQUAKE[J]. SEISMOLOGY AND GEOLOGY, 2020, 42(6): 1417-1431.

徐志国, 王君成, 王宗辰, 梁姗姗, 史健宇. 2019年11月14日印尼马鲁古海7.1级地震的震源机制及海啸数值模拟[J]. 地震地质, 2020, 42(6): 1417-1431.

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FOCAL MECHANISM AND TSUNAMI NUMERICAL SIMULATION OF THE NOVEMBER 14, 2019 MOLUCCA SEA M_W7.1 EARTHQUAKE

2019年11月14日印尼马鲁古海7.1级地震的震源机制及海啸数值模拟

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