Letouzey J, Kimura M. Okinawa Trough genesis:structure and evolution of a back-arc basin developed in a continent. Marine-and Petroleum Geology, 1985, 2: 111 ~ 130
[2]
Sibuet J C, Letouzey J, Barbier F, et al. Back-arc extension in the Okinawa Trough. J Geophys Res, 1987, 92:14 041 ~ 14063
[3]
Halbach P, Pracejus B, Maiten A, et al. Geology and mineralogy of massive sulfide ores from the central Okinawa Trough. Japan Econ Geol, 1993, 88:2 210~2 225
[4]
Halbach P, Nakamura K, Wahsner M, et al. Probable modem analogue of kuroko-type massive sulphide deposits in the Okinawa Trough back-arc basin. Nature, 1989, 338:496~499
[5]
Sakai H, Gamo T, Kim E-S, et al. Venting of carbon dioxide-rich fluid and hydrate formation in mid-Okinawa Trough backarc basin. Science, 1990, 248:1 093~1 096
[6]
Sakai H, Gamo T, Kim E-S, et al. Unique chemistry of the hydrothermal solution in the mid-Okinawa Trough backarc basin. Geophys Res Lett, 1990, 17:2 133~2 136
Kinoshita M, Yamano M. Hydrothermal regime and constraints on reservoir depth of the Jade site in the mid-Okinawa Trough inferred from heat flow measurements. J Geophys Res, 1997, 102(B2): 3 183~3 194
[9]
Hawkins J W, Melchior J T. Petrology of Mariana Trough and Lau Basin basalts. J Geophys Res, 1985, 90:11 431 ~ 11 468
[10]
Ueda A, Sakai H. Sulfur isotope study of Quaternary volcanic rocks from the Japanese island arc. Geochim Cosmochim Acta, 1984, 48:1 837~1 848
[11]
Woodhead J D, Harmon R S, Fraser D G, et al. O, S, Sr and Pb isotope variations in volcanic rocks from the northern Mariana Islands:implications for crustal recycling in intra-oceanic arcs. Earth Planet Sci Lett, 1987, 83: 39~52
[12]
Sakai H, DesMarais D J, Ueda A, et al. Concentrations and isotope ratios of carbon, nitrogen and sulfur in ocean-floor basalts. Geochim Cosmochim Acta, 1984, 48:2 433~2 441
Kusakabe M, Mayedn S, Nakamara E, et al. S, O and Sr isotope systematics of active vent materials from the Mariana backarc basin spreading axis at 18° N. Earth Planet Sci Lett, 1990, 100:275~282
[17]
Herzig P M, Hannington M D, Arribas A Jr, et al. Sulfur isotopic composition of hydrothermal precipitates from the Lau back-arc: implications for magmatic contributions to seafloor hydrothermal systems. Mineralium Deposita, 1998, 33: 226~237
[18]
Peter J M, Shanks Ⅲ W C. Sulfur, carbon, and oxygen isotope variations in submarine hydrothermal deposits of Guaymas Basin, Gulf of California, U S A. Geochim Cosmochim Acta, 1992, 56:2 025~2 040
[19]
Shanks W C Ⅲ, Seyfried W E Jr. Stable isotope studies of vent fluids and chimney minerals, southern Juan de Fuca Ridge:sodium metasomatism and seawater sulfate reduction. J Geophys Res, 1987, 92:11 387~11 399
[20]
Woodruff L G, Shanks W C. Sulfur isotope study of chimney minerals and hydrothermal fluids from 21° N, East Pacific Rise:hydrothermal sulfur sources and disequilibrium sulfate reduction. J Geophys Res, 1988, 93:4 562~4 572
[21]
Gamo T, Sakai H, Kim E-S, et al. High alkalinity due to sulfate reduction in the Clam hydrothermal field, Okinawa Trough. Earth Planet Sci Lett, 1991, 107:328~338
[22]
Bowers T S. Stable isotope signatures of water - rock interaction in mid - ocean ridge hydrothermal systems: sulfur, oxygen, and hydrogen. J Geophys Res, 1989, 94:5 775~5 786
[23]
郑永飞,傅斌,张学华岩浆去气作用的碳硫同位素效应.地质科学,1996,31:43~53
[24]
Marty B, Jambon A, Sano Y, et al. Helium isotopes and CO2 in volcanic gases of Japan. Chem Geol, 1989, 76: 25~40
