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 M (領域外・複数領域) » M-IS ジョイント

[M-IS22_29PM1] ガスハイドレートと地球環境・資源科学

2014年4月29日(火) 14:15 〜 16:00 213 (2F)

コンビーナ:*戸丸 仁(千葉大学理学部地球科学科)、八久保 晶弘(北見工業大学環境・エネルギー研究推進センター)、森田 澄人(独立行政法人 産業技術総合研究所 地圏資源環境研究部門)、座長:八久保 晶弘(北見工業大学環境・エネルギー研究推進センター)、戸丸 仁(千葉大学理学部地球科学科)

15:45 〜 16:00

[MIS22-07] サハリン島南東・南西沖の天然ガスハイドレートの特徴

*八久保 晶弘1坂上 寛敏1南 尚嗣1山下 聡1高橋 信夫1庄子 仁1Vereshchagina Olga2Jin Young K.3Obzhirov Anatoly2 (1.北見工業大学、2.ロシア科学アカデミー太平洋海洋学研究所、3.韓国極地研究所)

キーワード:ガスハイドレート, 安定同位体, オホーツク海, ラマン分光分析, 熱分析

Gas hydrate samples were retrieved at the southeastern and southwestern Sakhalin Island in the cruises of LV59 and LV62 (R/V Akademik M. A. Lavrentyev). Sakhalin Slope Gas Hydrate (SSGH) project started in 2007, and we retrieved sediment cores including gas hydrates off northeastern Sakhalin Island in 2009-2011. In the recent cruises (2012-2013), we sampled sediment cores at the Terpeniya Ridge and the Tatarsky Trough (SE and SW Sakhalin Island, respectively). We found a lot of gas plumes ascend from the sea bottom and the dissolved methane in sediment pore water was rich. Gas hydrate crystals were recovered from both areas and stored into liquid nitrogen tank. Their dissociation heat and hydration number were measured by a calorimeter and Raman spectrometer, respectively. Dissociation heat of gas hydrates was almost the same as that of pure methane hydrate. Raman spectra showed that the hydrate crystals of both Terpeniya Ridge and Tatar Trough belonged to the structure I, and the hydration number was estimated about 6.0. Molecules of hydrogen sulfide were detected in both large and small cages of the structure I. Therefore, the hydrate crystal is similar to that obtained from NE Sakhalin Island in our previous cruises. We obtained hydrate-bound gas and dissolved gas in pore water on board and measured their molecular and stable isotope compositions. Empirical classification of the methane stable isotopes; δ13C and δD indicated that the gases obtained at the Terpeniya Ridge are microbial origin via carbonate reduction, whereas some cores at the Tatarsky Trough showed typical thermogenic origin. We retrieved three sediment cores with gas hydrate at the Tatarsky Trough, and their δ13C of hydrate-bound methane were -47.5‰, -44.2‰, and -68.8‰, respectively. Therefore, gas hydrates encaged both microbial and thermogenic gases yield at the Tatarsky Trough. Ethane-rich (up to 1% of the total guest gas) hydrates were found at the Terpeniya Ridge and the Tatarsky Trough, and encaged ethane was also detected in their Raman spectra. Ethane δ13C of the all gas samples suggested their thermogenic origin.