日本地球惑星科学連合2019年大会

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[J] 口頭発表

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-CG57] 日本列島の構造と進化: 島弧の形成から巨大地震サイクルまで

2019年5月29日(水) 09:00 〜 10:30 A09 (東京ベイ幕張ホール)

コンビーナ:佐藤 比呂志(東京大学地震研究所地震予知研究センター)、篠原 雅尚(東京大学地震研究所)、石川 正弘(横浜国立大学大学院環境情報研究院)、松原 誠(防災科学技術研究所)、座長:篠原 雅尚(東京大学地震研究所観測開発基盤センター)、石山 達也(東京大学地震研究所)

09:30 〜 09:45

[SCG57-03] 渡島半島横断深部反射法地震探査

*佐藤 比呂志1石山 達也1加藤 直子1清水 英彦2佐藤 壮3川崎 慎治2野 徹雄3小平 秀一3三浦 誠一3 (1.東京大学地震研究所、2.地球科学総合研究所、3.海洋研究開発機構)

キーワード:深部反射法地震探査、震源断層、北海道南西部

An onshore-offshore seismic data set was collected across the Oshima peninsula, SW Hokkaido to the Japan basin, off SW-Hokkaido to determine the geometry of seismogenic source faults and basic structure of backarc of NE Honshu arc (Sato, T. et al., 2019 JpGU; No et al., 2019, JpGU). Here, we present the result of deep seismic reflection profiling across the Oshima peninsula, high-reslolution seismic reflection survey across the western boundary fault of Hakodate plain and P-wave velocity structure obtained from onshore-offshore integrated seismic processing.

The deep seismic data set was collected across the Oshima peninsula in May, 2018. Vertical land seismometers (GSR) were deployed with a spacing 50 to 200 m along the 54-km-long seismic line using fixed 1119 channel. The seismic source was four to five vibroseis trucks with standard 150 m shot spacing. As high energy shot, 50 stationary sweep were carried out every 5 km along the seismic line. Sweep frequency was 6 to 60 Hz and sweep length was 16 to 20 sec. The obtained seismic data were processed according to a standard common-midpoint (CMP) stacking and a post stack time migration. We used refraction tomography to determine the P-wave velocity structure, that revealed down to 8 km in depth beneath the western part of the seismic line. Obtained P-wave velocity profile demonstrates the geometry of the top surface of pre-Tertiary rocks. The Kamiiso massif and Esashi range marked by high Vp (> 5 km/s) and 2 km of sediment cover are distributed in the Tate and Hakodate Basins. With a pattern of seismic reflection, main geologic structure is interpreted a series of westward dipping Miocene normal faults. The NS-trending Kamiiso massif is an uplifted zone bounded by a high-angle reverse fault, which formed as a normal fault. The high-resolution seismic reflection profiling was performed across the western boundary fault of the Hakodate plain. Seismic source was a viborseis truck and the seismic signal was recorded fixed 845 channel offline recorders (GSR). Shot and receiver intervals are 10 m. The 8-km-long seismic section portrays the geometry of active fault down to 2 km in depth. The fault dips 45 degrees westward in more than one km depth. Judging from the stratigraphy, it is interpreted as a reactivation of normal fault as reverse fault. On the contrary, the shallower part of active fault forms thin-skinned type of deformation associated with wedge-thrust, fault-related fold and flat-ramp structure. The obtained shallow structure is very concordant with the feature of tectonic geomorphology and frontal part of active thrust is presented as a blind thrust. The air-gun shots along the offshore of Oshima peninsula were recorded by fixed recorders on land and integrated P-wave velocity was obtained covering 310 km seismic line. The basic feature is very similar to the velocity model proposed by Sato, T. et al. (2019) JpGU. The velocity structure portrays the detailed structure produced by Miocene backarc extension and formation of the Sea of Japan crust. In spite of the later shortening deformation, basic structure has extensional tectonic features. There no evidence of the subduction of the Sea of Japan crust beneath the Hokkaido continental crust.