Japan Geoscience Union Meeting 2021

Presentation information

[J] Oral

M (Multidisciplinary and Interdisciplinary) » M-IS Intersection

[M-IS21] Chemosynthetic community and mud volcano: biology, geochemistry, and geophysics of fluid discharge

Thu. Jun 3, 2021 10:45 AM - 12:15 PM Ch.25 (Zoom Room 25)

convener:Yusuke Miyajima(Geomicrobiology Research Group, Research Institute for Geo-Resources and Environment, Geological Survey of Japan, National Institute of Advanced Industrial Science and Technology), Kayama Hiromi WATANABE(Japan Agency for Marine-Earth Science and Technology), Akira Ijiri(Japan Agency for Marine-Earth Science and Technology), Tomohiro Toki(Faculty of Science, University of the Ryukyus), Chairperson:Yusuke Miyajima(Geomicrobiology Research Group, Research Institute for Geo-Resources and Environment, Geological Survey of Japan, National Institute of Advanced Industrial Science and Technology), Hiromi Kayama WATANABE(Japan Agency for Marine-Earth Science and Technology)

10:45 AM - 11:00 AM

[MIS21-01] Characteristic and Origin of erupted sediments in submarine mud volcanoes, off Tanegashima Island

*Ryoma Setoguchi1, Akira Ijiri2, Takeyasu Yamagata3, Hiroyuki Matsuzaki3, Kyoko Hagino1, Juichiro Ashi4, Masafumi MURAYAMA1 (1.Kochi University, 2.Japan Agency for Marine-Earth Science and Technology, 3.The University Museum, The University of Tokyo, 4.Atmosphere and Ocean Research Institute, The University of Tokyo)


Keywords:Mud Volcano, Submarine Mud Volcano, Methane Gas, Clay mineral

Mud volcanoes are remarkable geological features formed by the vertical intrusion of low density and deformable sediments from deep subsurface to the surface, and are distributed both on land and seafloor at the continental margins. The mud volcanoes are an important source of methane to the hydrosphere and the atmosphere. In the sea around Japan, it is widely distributed in the Kumano Basin off the Kii Peninsula and off Tanegashima Island. The mud volcanoes in the Kumano Basin are well studied compared to those off Tanegashima, and the mechanism of the eruption has been inferred from fluid and sediment analyses. So far, 15 mud volcanoes have been identified in topographic surveys off Tanegashima Island and numbered from MV#1 to #15. During the KH-15 and KH-19 cruises in 2015 and 2019 by R/V Hakuho-Maru, we retrieved piston cores from MV#1 (30o53´N, 131o46´E; water depth: 1540 m), #2 (30o55´N, 131o50´E; water depth: 1430 m) , #3 (31o03´N, 131o41´E; water depth: 1200 m) , and #14 (30o11´N, 131o23´E; water depth: 1700 m) . We investigated the origin of sediments and fluids based on the chemical analyses of them. For the sediment cores, the internal structure was observed by X-ray CT, and the sediment age was estimated by 10Be and calcareous nannofossils. Bulk mineral composition and clay mineral compositions were estimated by XRD analysis, and then the temperature history of sediments was estimated from the clay mineral composition. The origin of methane were investigated by the methane to ethane concentration ratio (C1/C2), and the carbon isotopic composition (δ13C) of methane. The sediments of MVs # 1, # 2, and #3 contain a large amount of mud breccia, and the modern hemi-pelagic sediments covered on the erupted sediments were not observed, suggesting that those mud volcanoes are active. On the other hand, nannofossils observations suggest that MV # 14 is dormant mud volcano in which the hemi-pelagic Quaternary sediments have covered on the erupted sediments. The nannofossil ages and the 10Be ages of MVs#2 and #3 consistently show the Middle to Late Miocene. These ages are younger than the Eocence Shimanto belt distributed around Tanegashima (Ujiie et al., 2000), suggesting that the mud-volcano sediments are provided from the sedimentary layers above the Shimanto belt. The mud-volcano sediments were generally dominated in quartz, illite, and plagioclase, and there is no particular mineralogical difference among the mud volcanoes. Clay minerals were mostly dominated in illite, suggesting the experience 60–160 oC where smectite to illite transformation occurs. There were some differences in clay mineral composition among the mud volcanoes. The illite/smectite mixed-layer (I/S) was detected in MV # 1, but not detected in MVs #2, #3, and #14. In MV #1, the illite content in the I/S mixed-layer, estimated from the diffraction pattern, is 42 to 45%. The content indicates the early stage of illitization, suggesting that the experienced temperature is 60 to 100 oC. On the other hand, the MVs#2, #3 and #14 sediments, in which the mixed-layer was not detected, might be experienced higher temperatures than MV#1, due to the progress of smectite to illite transformation. At the active MVs #1, # 2, and #3, generally low C1/C2 ratio (30–50) and δ13C of methane (-57‰ – -42‰) indicate that the hydrocarbon gases are derived from thermal decompositions of organic matter in deep sediments where the in situ temperature is >80oC. At the inactive MV#14, the C1/C2 ratios were high as 700–4000, and δ13C of methane were -75‰ and -77‰, respectively. The data indicate the biogenic origin. Considering the geothermal gradient (25–50 oC/km) observed in the area, the conditions for thermogenic gas production (> 80 oC), and the temperature history of the sediments, the sediments and hydrocarbon gas would be provided from deep sedimentary realm deeper than 1.5 km below seafloor.