日本地球惑星科学連合2023年大会

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[E] オンラインポスター発表

セッション記号 S (固体地球科学) » S-CG 固体地球科学複合領域・一般

[S-CG45] Science of slow-to-fast earthquakes

2023年5月26日(金) 10:45 〜 12:15 オンラインポスターZoom会場 (16) (オンラインポスター)

コンビーナ:加藤 愛太郎(東京大学地震研究所)、山口 飛鳥(東京大学大気海洋研究所)、濱田 洋平(独立行政法人海洋研究開発機構 高知コア研究所)、Yihe Huang(University of Michigan Ann Arbor)

現地ポスター発表開催日時 (2023/5/25 17:15-18:45)

10:45 〜 12:15

[SCG45-P34] Seismic Imaging of the Subducted Seamount in a High-Tremor Seismicity Region in the Hyuga-nada, Nankai Trough

*馬 妍雪1仲田 理映1望月 公廣1橋本 善孝2濱田 洋平3新井 隆太4三浦 誠一4中村 恭之4藤江 剛4海宝 由佳4小平 秀一4 (1.東京大学地震研究所、2.高知大学、3.国立研究開発法人海洋研究開発機構高知コア研究所、4.国立研究開発法人海洋研究開発機構)


キーワード:seismic imaging、seismic processing、subducted seamount、slow earthquakes、Nankai Trough、traveltime tomography

Hyuga-nada is located offshore southwestern Japan. The Kyushu Palau Ridge (KPR) separates the Ryukyu Trench and the Nankai Trough. Shallow slow earthquakes, such as tremors and very low-frequency earthquakes, have been detected by broadband ocean bottom seismometers around the subducted seamount located in the northwestern part of the KPR. Some studies suggest that subducted seamounts under tectonic plates may increase friction, acting as inter-seismic locking asperities. This can result in an increase of stress or strain energy in the surrounding region. Others propose that subducted seamounts act as barriers that prevent earthquake rupture propagation by creating areas of low stress.

To better understand the relationship between seamount subduction and seismic activity, we analyzed the KR0114-8 reflection line that intersects the KPR and nearly perpendicular to the subduction direction.Our high-resolution seismic image revealed various clear lithological boundaries, including various clear lithological boundaries, such as bottom-simulating reflectors, faults, the accretionary prism, the décollement, and the basement (Figure 1b and c). By comparing the distribution of shallow tectonic tremors with the reflection section image, we found that the tremors were predominantly located in the Ryukyu Trench and Nankai Trough zones (Figure 1a). On the contrary, few tremors occurred above the subducted seamount, suggesting a stress shadow. Within the Nankai Trough zone, a larger number of tremors occurred close to the trough where the underthrust sediments between the décollement and the basement are thick, and where the in-sequence thrusts develop in the accretionary prism. A smaller number of tremors occurred where the décollement and basement topography is rough. The décollement is indicated by a strong reflector with a negative polarity, and its larger amplitude near the trough suggests a larger impedance contrast between the accretionary prism and the underthrust sediments when compared to that close to the KPR. If we assume that velocity of the underthrust sediment is constant across the Nankai Trough zone, the velocity above the décollement is slower near the trough than near the KPR. The rich tremor distribution may indicate that pore pressure is elevated in the apparent lower velocity area.

To further constrain the model of seamount subduction and geological features, we are analyzing the HYU02 line that is parallel to the subducting direction and intersects with the KR0114-8. We apply travel time inversion analysis to the HYU02 refraction data. We will present a preliminary result and discuss geological interpretation. Our result will provide a new case example of seamount subduction, and contribute to a more complete understanding of the relationship between subducted seamounts and seismicity, and how these processes impact the stress state and fluid pressure distribution.