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Stable Isotope Analysis of Natural Gas Hydrate in the Sea of Okhotsk

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dc.contributor.authorAKIHIRO HACHIKUBO-
dc.contributor.authorNOBUO TAKAHASHI-
dc.contributor.authorANAROLY OBZHIROV-
dc.contributor.authorHIROTOSHI-
dc.contributor.authorTATIANA MATVEEVA-
dc.contributor.authorJin, Young Keun-
dc.contributor.authorHITOSHI SHOJI-
dc.contributor.authorHIROTSUGU MINAMI-
dc.contributor.authorALEXEY KRYLOV-
dc.contributor.authorTOMOKO KOSAKA-
dc.coverage.spatialSea of Okhotsk-
dc.date.issued2008-
dc.identifier.urihttps://repository.kopri.re.kr/handle/201206/7868-
dc.description.abstractNatural gas hydrates have been recovered from the seepage structures offshore Sakhalin, in the Sea of Okhotsk. Field cruises were executed from 2003 to 2007 within the framework of the CHAOS project (hydroCarbon Hydrate Accumulations in the Okhotsk Sea). Hydrate-bearing sediments were retrieved by gravity coring in CHAOS1 (Oct. 2003) and CHAOS2 (May 2005). A genetic classification diagram for natural gas using methane isotopes was proposed [1] and applied it to interpret origin of gas hydrates in the world [2]. In this diagram, large and small δ13C of methane indicate thermogenic and microbial origins, respectively, and δD of methane also provides information on methyl-type fermentation or CO2 reduction in the microbial origin. We would like to show characteristics of the seepage structures offshore Sakhalin from the viewpoints of isotopic composition and gas concentration. Gas hydrate samples were obtained from six seepage structures named Hieroglyph, Kitami, CHAOS, KOPRI, VNIIOkeangeologia and GISELA. δ13C and δD of dissociated gases were measured by using GC-IRMS (DELTA plus XP-
dc.description.abstractThermo Finnigan) in Kitami Institute of Technology. Methane δ13C and δD were in the range -65 to -62‰ and -205 to -195‰, respectively. These results indicate a microbial origin produced by CO2 reduction according to Whiticar's diagram. Ethane concentration was 30-150ppm for hydrate-bearing sediments and 10-100ppm for non-hydrate sediments, and depended on each seepage structure. We discussed the formation process of gas hydrate in the shallow sediment cores according to the experimental results of isotopic fractionation at the formation of gas hydrates [3].-
dc.languageEnglish-
dc.titleStable Isotope Analysis of Natural Gas Hydrate in the Sea of Okhotsk-
dc.title.alternative오호츠크해 천연가스하이드레이트의 동위원소 분석-
dc.typeProceeding-
dc.identifier.bibliographicCitationAKIHIRO HACHIKUBO, et al. 2008. Stable Isotope Analysis of Natural Gas Hydrate in the Sea of Okhotsk. AOGS. AOGS. 2008.06.16~.-
dc.citation.volume1-
dc.citation.number1-
dc.citation.conferenceDate2008.06.16~-
dc.citation.conferenceNameAOGS-
dc.citation.conferencePlaceAOGS-
dc.description.articleClassificationPro(초록)국외-
dc.subject.keywordCHAOS-
dc.subject.keywordSea of Okhotsk-
dc.subject.keywordgas hydrate-
dc.subject.keywordseepage structure-
dc.subject.keywordstable isotope-
dc.identifier.localId2008-0217-
Appears in Collections  
2004-2011, Oceanographic Research on the Arctic Sea (04-11) / Chung, Kyung Ho; Lee, Sang Heon (PM27800, PM05010, PM07020, PM10040, PM06020, PM08030, PM09020, PM11050)
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