日本地球惑星科学連合2014年大会

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セッション記号 S (固体地球科学) » S-IT 地球内部科学・地球惑星テクトニクス

[S-IT41_28AM2] 海洋プレートの一生:誕生から解体,そして復活

2014年4月28日(月) 11:00 〜 12:45 314 (3F)

コンビーナ:*森下 知晃(金沢大学理工研究域自然システム学系)、山崎 俊嗣(東京大学大気海洋研究所)、島 伸和(神戸大学大学院理学研究科地球惑星科学専攻)、安間 了(筑波大学生命環境系)、熊谷 英憲(独立行政法人海洋研究開発機構)、中村 大輔(岡山大学)、座長:新井 隆太(School of Ocean and Earth Science and Technology, University of Hawaii)、松野 哲男(国立極地研究所)

11:45 〜 12:00

[SIT41-07] 中央インド洋海嶺ヨコニワ熱水域における高磁化帯の起源

*藤井 昌和1沖野 郷子1佐藤 太一2佐藤 暢3中村 謙太郎4 (1.東京大学大気海洋研究所、2.産業技術総合研究所、3.専修大学、4.東京大学)

キーワード:海底熱水系, 中央海嶺, 超塩基性岩, 深海磁気異常, オフアクシス火成活動, 海洋性地殻

Measurement of near bottom magnetic anomalies is an effective method to reveal the spatial extent of hydrothermal alteration zone and to find buried hydrothermal vent fields because hydrothermal alteration processes can change crustal magnetization by destruction and creation of magnetic minerals. In the Yokoniwa vent field (YVF), which is located at the top of the non-transform offset massif, called the Yokoniwa Rise, in the southernmost part of the Central Indian Ridge, a high magnetization zone was discovered by AUV r2D4 in 2009. Basalts and ultramafic rocks were found around the YVF, however the origin of positive magnetization and the relationships between high magnetization and hydrothermal activity are remains to be investigated. In order to constrain the origin of magnetic source near the YVF, we conducted deep-sea geological observation and magnetic measurements using submersible Shinkai 6500 during the R/V Yokosuka cruises, YK09-13 and YK13-03. Vector geomagnetic field were successfully obtained along the all dive tracks at an altitude of ~ 10 m. The distribution of crustal magnetization is estimated by vertical and horizontal components of magnetic anomalies using the 2-dimesional forward modeling technique and frequency analysis.In the southern slope of the Yokoniwa Rise, serpentinized-peridotites were discovered and absolute magnetization shows entirely low (~6 A/m). On the other hand, just around the YVF, hydrothermal sulfide deposits, tiny dead chimneys, shimmering and talc were observed and absolute magnetization shows relatively high (9 A/m). This magnetization contrast between the YVF and the surrounding area may be attributed to the difference in amount of magnetite, controlled by the degree and the temperature of serpentinization. One of the serpentinized-peridotite recovered during the cruises showed large amount of magnetite and high natural remanent magnetization. However, the highest absolute magnetization (20 A/m) was discovered at pillow basalt area with thin sediment just ~700 m away from the YVF, implying recent off-axis volcanic activity. Therefore basaltic intrusion beneath the YVF is also possible for the origin of high magnetization. In addition, magnetic iron sulfide (pyrrhotite) grown during hydrothermal circulation, which is proposed at the Rainbow hydrothermal vent field, is also possible. Consequently, we proposed three possibilities for the origin of high magnetization at the YVF; serpentinized peridotites with high temperature hydrothermal alteration, basaltic intrusion bodies, and pyrrhotites concentration. All of these hypotheses are related to hydrothermal activity. For the further inspection, recovering subseafloor rocks and inspection of rock magnetic properties are absolutely necessary.