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AMS 14C Measurements of Dissolved Inorganic Carbon in Pore Waters from a Deep-Sea “Cold Seep” Giant Clam Community Off Hatsushima Island, Sagami Bay, Japan

Published online by Cambridge University Press:  18 July 2016

Toshiyuki Masuzawa
Affiliation:
Institute for Hydrospheric-Atmospheric Sciences, Nagoya University, Nagoya 464-01 Japan
Hiroyuki Kitagawa
Affiliation:
International Research Center for Japanese Studies, Kyoto 610-11 Japan. Present address: Center for Isotope Research, Nijenborgh 4, NL-9747 AG Groningen, The Netherlands
Takeshi Nakatsuka
Affiliation:
Institute for Hydrospheric-Atmospheric Sciences, Nagoya University, Nagoya 464-01 Japan
Nobuhiko Handa
Affiliation:
Institute for Hydrospheric-Atmospheric Sciences, Nagoya University, Nagoya 464-01 Japan
Toshio Nakamura
Affiliation:
Dating and Material Research Center, Nagoya University, Nagoya 464-01 Japan
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Abstract

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We collected pore waters using an in situ pore water-squeezer for a submersible Shinkai 2000 at six depths beneath the sediment surface within a deep-sea “cold seep” giant clam community off Hatsushima Island, Sagami Bay, Japan. A box core sample was also collected ca. 4.5 km east of the community and pore waters were separated. Dissolved inorganic carbon (DIC) was extracted and purified in a vacuum line and 14C concentration was determined with a Tandetron accelerator mass spectrometer at Nagoya University after conversion to graphite targets using a batch Fe-catalytic hydrogen reduction method. ∆14C values decreased with increasing depth to −938‰ at the sulfate concentration minimum. This indicates that methane used for the active reduction of sulfate and formation of hydrogen sulfide, which is used by symbiotic chemoautotrophic bacteria in gills of the giant clams, is almost dead and is likely supplied from the deep. ∆14C values of DIC vary linearly with δ13C values along a mixing line between that in the bottom water and that produced by the oxidation of dead methane. The δ13C value of DIC oxidized from dead methane is estimated to be ca. −45‰.

Type
V. Advances in Measurement Techniques
Copyright
Copyright © the Department of Geosciences, The University of Arizona 

References

Alperin, M. J. and Reeburgh, W. S. 1984 Geochemical observations supporting anaerobic methane oxidation. In Crawford, R. L. and Hanson, R. S., eds., Microbial Growth on C-1 Compounds. Washington, D.C., American Society of Microbiology: 282289.Google Scholar
Alperin, M. J., Reeburgh, W. S. and Whiticar, M. J. 1988 Carbon and hydrogen isotope fractionation resulting from anaerobic methane oxidation. Global Biogeochemical Cycles 2: 279288.Google Scholar
Druffel, E. R. M. and Williams, P. M. 1990 Identification of a deep marine source of particulate organic carbon using bomb 14C. Nature 347:172174.CrossRefGoogle Scholar
Gamo, T. and Sakai, H. 1989 Development of a semi-automated multi water sampling system for determining chemical flux of bottom fluid venting off Hatsushima Island, Sagami Bay. JAMSTEC Deepsea Research 5: 317323.Google Scholar
Hashimoto, J., Ohta, S., Tanaka, T., Hotta, H., Matsuzawa, S. and Sakai, H. 1989 Deep-sea communities dominated by the giant clam Calyptogena soyoae, along the slope foot of Hatsushima Island, Sagami Bay, central Japan. Palaeogeography, Palaeoclimatology and Palaeoecology 71: 179192.Google Scholar
Hassan, A. A. 1982 Methodologies for extraction of dissolved inorganic carbon for stable carbon isotope studies: Evaluation and alternatives. U.S. Geological Survey Water-Resources Investigations 82–6: 51pp.Google Scholar
Jannasch, H. W. and Mottl, M. J. 1985 Geomicrobiology of deep-sea hydrothermal vents. Science 229: 717725.CrossRefGoogle ScholarPubMed
Kennicutt II, M. C., Brooks, J. M., Bidigare, R. R., Fay, R. R., Wade, T. L. and McDonald, T. J. 1985 Vent-type taxa in a hydrocarbon seep region on the Louisiana slope. Nature 317: 351353.Google Scholar
Kitagawa, H., Masuzawa, T., Nakamura, T. and Matsumoto, E. 1993 A batch preparation method for graphite targets with low background for AMS 14C measurements. Radiocarbon 35(2): 295300.CrossRefGoogle Scholar
Libes, S. M. 1992 An Introduction to Marine Biogeochemistry. New York, John Wiley & Sons: 734 p.Google Scholar
Masuzawa, T., Handa, N., Kitagawa, H. and Matsumoto, E. 1990 Pore water sampling with an in situ pore water squeezer from sediments within a deep-sea giant clam colony off Hatsushima Island, Sagami Bay, Japan: Dive 449 of the submersible Shinkai 2000. JAMSTEC Deepsea Research 6: 197204.Google Scholar
Masuzawa, T., Kitagawa, H. and Handa, N. 1991 Pore water sampling with an in situ pore water squeezer from sediments within a deep-sea giant clam colony off Hatsushima Island, Sagami Bay, Japan: Part 2. Dive 521 of the submersible Shinkai 2000. JAMSTEC Deepsea Research 7: 715.Google Scholar
Masuzawa, T., Handa, N., Kitagawa, H. and Kusakabe, M. 1992 Sulfate reduction using methane in sediments beneath a bathyal “cold seep” giant clam community off Hatsushima Island, Sagami Bay, Japan. Earth and Planetary Science Letters 110: 3950.CrossRefGoogle Scholar
Minagawa, M., Winter, D. and Kaplan, I. R. 1984 Comparison of Kjeldahl and combustion methods for measurement of nitrogen isotope ratios in organic matter. Analytical Chemistry 56: 18591861.CrossRefGoogle Scholar
Nakamura, T., Nakai, N. and Ohishi, S. 1987 Techniques of tandem accelerator mass spectrometry and their applications to 14C measurements. Nuclear Instruments and Methods in Physics Research B29: 335360.Google Scholar
Paull, C. K., Hecker, B., Commeau, R., Freeman-Lynde, R. P., Neumann, C., Corso, W. P., Golubic, S., Hook, J. E., Sikes, E. and Curray, J. 1984 Biological communities at the Florida Escarpment resemble hydrothermal vent taxa. Science 226: 965967.Google Scholar
Paull, C. K., Martens, C. S., Chanton, J. P., Neumann, A. C., Coston, J., Jull, A. J. T. and Toolin, L. J. 1989 Old carbon in living organisms and young CaCO3 cements from abyssal brine seeps. Nature 342:166167.CrossRefGoogle Scholar
Ohta, S. and Laubier, L. 1987 Deep biological communities in the subduction zone of Japan from bottom photographs taken during “Nautile” dives in the Kaiko project. Earth and Planetary Science Letters 83: 329342.CrossRefGoogle Scholar
Okutani, T. and Egawa, K. 1985 The first underwater observation on living habitat and thanatocoenoses of Calyptogena soyoae in bathyal depths of Sagami Bay. Venus (Japanese Journal of Malacology) 44: 285289.Google Scholar
Östlund, H. G. and Stuiver, M. 1980 GEOSECS Pacific radiocarbon. Radiocarbon 22(1): 2553.Google Scholar
Sakai, H., Gamo, T., Endow, K., Ishibashi, J., Ishizuka, T., Yanagisawa, F., Kusakabe, M., Akagi, T., Igarashi, J. and Ohta, S. 1987 Geochemical study of the bathyal seep communities at the Hatsushima site, Sagami Bay, Central Japan. Geochemical Journal 21: 227236.CrossRefGoogle Scholar
Suess, E., Carson, B., Ritger, S. D., Moore, J. C., Jones, M. L., Kulm, L. D. and Cochrane, G. R. 1985 Biological communities at vent sites along the subduction zone off Oregon. Biological Society of Washington Bulletin 6: 475484.Google Scholar
Stuiver, M. and Polach, H. A. 1977 Discussion: Reporting of 14C data. Radiocarbon 19(3): 355363.Google Scholar
Whiticar, M. J., Faber, E. and Schoell, M. 1986 Biogenic methane formation in marine and freshwater environments: CO2 reduction vs. acetate fermentation—Isotope evidence. Geochimica et Cosmochimica Acta 50: 693709.Google Scholar