The deep structure of the Duanqiao hydrothermal field at the Southwest Indian Ridge
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摘要: 多金属硫化物是海底热液活动的主要产物,因其富含多种贵金属元素,成为一种重要的海底矿产资源。2007年以来,中国大洋调查航次在西南印度洋脊开展了多个航次的海底热液活动调查。并于2011年,中国大洋矿产资源研究开发协会与国际海底管理局签署了西南印度洋脊一万平方公里的多金属硫化物勘探合同。利用2010年DY115-21航次第六航段多波束数据及船测重力数据以和全球卫星数据,分析了西南印度洋中国多金属硫化物勘探合同区内“断桥”热液区(点)(50°24'E ,37°39'S)的重力异常特征,采用“分区校正”地形改正方法计算了布格重力异常,并以OBS剖面结构为约束,进行了重力异常2-D模拟。计算出了地震反演结果中缺失的Moho面。结果发现沿剖面地壳厚度变化在3-10km之间;“断桥”热液区地壳最厚处达10km,平均厚度在7.5km左右,是目前为止在西南印度洋中脊上发现的最厚地壳;“龙旂”热液区地壳厚度约3km,对比地震结果要薄1km,可能受到周围OCC比较薄的影响。认为“断桥”热液区为海底多金属硫化物成矿有利地带。Abstract: Polymetalic sulfide is the main product of sea-floor hydrothermal venting, and has become an important sea-floor mineral resources for its rich in many kinds of precious metal elements. Since 2007, a number of investigations have been carried out by the China Ocean Mineral Resources Research and Development Association (COMRA ) cruises (CCCs) along the Southwest Indian Ridge (SWIR). In 2011, the COMRA signed an exploration contract of sea-floor polymetallic sulfides of 10 000 km2 on the SWIR with the International Seabed Authority. Based on the multibeam data and shipborne gravity data obtained in 2010 by the R/V Dayang Yihao during the leg 6 of CCCs 21, together with the global satellite surveys, the characteristics of gravity anomalies are analyzed in the Duanqiao hydrothermal field (37°39'S, 50°24'E). The “subarea calibration” terrain-correcting method is employed to calculate the Bouguer gravity anomaly, and the ocean bottom seismometer (OBS) profile is used to constrain the two-dimensional gravity anomaly simulation. The absent Moho in a previous seismic model is also calculated. The results show that the crustal thickness varies between 3 and 10 km along the profile, and the maximum crustal thickness reaches up to 10 km in the Duanqiao hydrothermal field with an average of 7.5 km. It is by far the most thicker crust discovered along the SWIR. The calculated crust thickness at the Longqi hydrothermal field is approximately 3 km, 1 km less than that indicated by seismic models, possibly due to the outcome of an oceanic core complex (OCC).
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Alt J C. 2003. Hydrothermal fluxes at mid-ocean ridges and on ridge flanks. Comptes Rendus Geoscience, 335(10-11): 853-864 Asimow P D, Langmuir C H. 2003. The importance of water to oceanic mantle melting regimes. Nature, 421(6925): 815-820 Baker E T, Chen Y J, Jason P M. 1996. The relationship between near-axis hydrothermal cooling and the spreading rate of mid-ocean ridges. Earth and Planetary Science Letters, 142(1-2): 137-145 Baker E T, German C R. 2004. On the global distribution of hydrothermal vent fields. In: German C R, Lin Jian, Parson L M, et al., eds. Mid-Ocean Ridges: Hydrothermal Interactions Between the Lithosphere and Oceans. Washington DC: American Geophysical Union, 245-266 Cannat M, Rommevaux-Jestin C, Sauter D, et al. 1999. Formation of the axial relief at the very slow spreading Southwest Indian Ridge (49° to 69°E). Journal of Geophysical Research, 104(B10): 22825-22843 Cannat M, Sauter D, Mendel V, et al. 2004. Spreading geometry and melt supply at the ultraslow-spreading Southwest Indian Ridge. In: AGU Fall Meeting Abstracts 2004. v 1. Washington DC: American Geophysical Union, 3 Cannat M, Sauter D, Mendel V, et al. 2006. Modes of seafloor generation at a melt-poor ultraslow-spreading ridge. Geology, 34(7): 605-608 Charlou J L, Fouquet Y, Donval J P, et al. 1996. Mineral and gas chemistry of hydrothermal fluids on an ultrafast spreading ridge: east Pacific Rise, 17° to 19°S (Naudur cruise, 1993) phase separation processes controlled by volcanic and tectonic activity. Journal of Geophysical Research, 101(B7): 15899-15919 Chen Y J. 1992. Oceanic crustal thickness versus spreading rate. Geophysical Research Letters, 19(8): 753-756 Dick H J B, Lin Jian, Schouten H. 2003. An ultraslow-spreading class of ocean ridge. Nature, 426(6956): 405-412 Dick H J B, Natland J H, Alt J C, et al. 2000. A long in situ section of the lower ocean crust: results of ODP leg 176 drilling at the Southwest Indian Ridge. Earth and Planetary Science Letters, 179(1): 31-51 Ding Liuhuai, Chen Ximing, Gao Yuqing. 2009. Seafloor massive sulfides: the frontier of deep ocean miming. Ocean Technology (in Chinese), 28(1): 126-132 Edmonds H N, Michael P J, Baker E T, et al. 2003. Discovery of abundant hydrothermal venting on the ultraslow-spreading Gakkel Ridge in the Arctic Ocean. Nature, 421(6920): 252-256 Escartín J, Smith D K, Cann J, et al. 2008. Central role of detachment faults in accretion of slow-spreading oceanic lithosphere. Nature, 455(7214): 790-794 Fisher R L, Goodwillie A M. 1997. The physiography of the Southwest Indian Ridge. Marine Geophysical Researches, 19(6): 451-455 Font L, Murton B J, Roberts S, et al. 2007. Variations in melt productivity and melting conditions along SWIR (70°–49°E): evidence from olivine-hosted and plagioclase-hosted melt inclusions. Journal of Petrology, 48(8): 1471-1494 Galley A G. 1993. Characteristics of semi-conformable alteration zones associated with volcanogenic massive sulphide districts. Journal of Geochemical Exploration, 48(2): 175-200 Gardner G H F, Gardner L W, Gregory A R. 1974. Formation velocity and density-the diagnostic basics for stratigraphic traps. Geophysics, 39(6): 770-780 Georgen J E, Kurz M D, Dick H J B, et al. 2003. Low 3He/4He ratios in basalt glasses from the western Southwest Indian Ridge (10°-24°E). Earth and Planetary Science Letters, 206(3-4): 509-528 Georgen J E, Lin Jian. 2003. Plume-transform interactions at ultra-slow spreading ridges: implications for the Southwest Indian Ridge. Geochemistry, Geophysics, Geosystems, 4(9): 9106 German C R, Lin Jian. 2004. The thermal structure of the oceanic crust, ridge-spreading and hydrothermal circulation: How well do we understand their Inter-Connections. In: German C R, Lin Jian, Parson L M, eds. Mid-Ocean Ridges: Hydrothermal Interactions Between the Lithosphere and Oceans. Washington DC: American Geophysical Union, 1-18 Ito G, Lin Jian, Gable C W. 1997. Interaction of mantle plumes and migrating mid-ocean ridges: implications for the Galápagos plume-ridge system. Journal of Geophysical Research, 102(B7): 15403-15417 Ito G, Shen Yang, Hirth G, et al. 1999. Mantle flow, melting, and dehydration of the Iceland mantle plume. Earth and Planetary Science Letters, 165(1): 81-96 LaCoste and Romberg Company. 2004. Model “S” Air-Sea Dynamic Gravity Meter System Ⅱ Instruction Manual. Austin: LaCoste and Romberg Company Li Jiabiao, Jian Hanchao, Chen Y J, et al. 2015a. Seismic observation of an extremely magmatic accretion at the ultraslow spreading Southwest Indian Ridge. Geophysical Research Letters, 42(8): 2656-2663 Li Sanzhong, Suo Yanhui, Liu Xin, et al. 2015b. Tectonic reconstruction and mineralization models of the Indian Ocean: insights from SWIR. Geotectonica et Metallogenia (in Chinese), 39(1): 30-43 Liu Weiyong, Zheng Lianfu, Tao Chunhui, et al. 2011. On the feature of seafloor hydrothermal systems' evolutionary and its mineralization in Mid-Ocean Ridge. Journal of Marine Sciences (in Chinese), 29(1): 25-33 Lowell B. 2008. Focus on Modeling: state of the art & future challenges. Ridge 2000 Events (summer), 5-9 Martin W, Baross J, Kelley D, et al. 2008. Hydrothermal vents and the origin of life. Nature Reviews Microbiology, 6(11): 805-814 Mendel V, Sauter D, Rommevaux-Jestin C, et al. 2003. Magmato-tectonic cyclicity at the ultra-slow spreading Southwest Indian Ridge: evidence from variations of axial volcanic ridge morphology and abyssal hills pattern. Geochemistry, Geophysics, Geosystems, 4(5): 9102 Meyzen C M, Toplis M J, Humler E, et al. 2003. A discontinuity in mantle composition beneath the Southwest Indian Ridge. Nature, 421(6924): 731-733 Minshull T A, Muller M R, White R S. 2006. Crustal structure of the Southwest Indian Ridge at 66°E: seismic constraints. Geophysical Journal International, 166(1): 135-147 Nath B N. 2007. Hydrothermal Minerals. Indian: National institute of Oceanography, 78-83 Niu Xiongwei, Ruan Aiguo, Li Jiabiao, et al. 2015. Along-axis variation in crustal thickness at the ultraslow spreading Southwest Indian Ridge (50°E) from a wide-angle seismic experiment. Geochemistry, Geophysics, Geosystems, 16(2): 468-485 Okino K, Matsuda K, Christie D M, et al. 2004. Development of oceanic detachment and asymmetric spreading at the Australian-Antarctic discordance. Geochemistry, Geophysics, Geosystems, 5(12): Q12012 Plank T, Langmuir C H. 1992. Effects of the melting regime on the composition of the oceanic crust. Journal of Geophysical Research, 97(B13): 19749-19770 Ribe N M. 1996. The dynamics of plume-ridge interaction: 2. Off-ridge plumes. Journal of Geophysical Research, 101(B7): 16195-16204 Ribe N M, Christensen U R, Theiβing J. 1995. The dynamics of plume-ridge interaction: 1. Ridge-centered plumes. Earth and Planetary Science Letters, 134(1-2): 155-168 Ruan Aiguo, Li Jiabiao, Niu Xiongwei, et al. 2014. Main characteristics of crustal structure of Southwest Indian Ridge. In: Committee of Information Technology, Chinese Geophysical Society. Abstract Set of Theses on Discussion and Application of Big Data, Cloud Computing and Geophysics (in Chinese). Shijiazhuang: Committee of Information Technology, Chinese Geophysical Society, 32-33 Sauter D, Cannat M. 2010. The ultraslow spreading Southwest Indian Ridge. In: Rona P A, Devey C W, Dyment J, et al., eds. Diversity of Hydrothermal Systems on Slow Spreading Ocean Ridges, Vol 88. Washington DC: American Geophysical Union, 153-173 Sauter D, Cannat M, Meyzen C, et al. 2009. Propagation of a melting anomaly along the ultraslow Southwest Indian Ridge between 46°E and 52°20'E: interaction with the Crozet hotspot. Geophysical Journal International, 179(2): 687-699 Sauter D, Mendel V, Rommevaux-Jestin C, et al. 2004. Focused magmatism versus amagmatic spreading along the ultra-slow spreading Southwest Indian Ridge: Evidence from TOBI side scan sonar imagery. Geochemistry, Geophysics, Geosystems, 5(10): Q10K09 Sauter D, Patriat P, Rommevaux-Jestin C, et al. 2001. The Southwest Indian Ridge between 49°15'E and 57°E: focused accretion and magma redistribution. Earth and Planetary Science Letters, 192(3): 303-317 Seyler M, Cannat M, Mével C. 2003. Evidence for major-element heterogeneity in the mantle source of abyssal peridotites from the Southwest Indian Ridge (52° to 68°E). Geochemistry, Geophysics, Geosystems, 4(2): 9101 Standish J J, Dick H J B, Michael P J, et al. 2008. MORB generation beneath the ultraslow spreading Southwest Indian Ridge (9°–25°E): major element chemistry and the importance of process versus source. Geochemistry, Geophysics, Geosystems, 9(5): Q05004 Standish J J, Sims K W W. 2010. Young off-axis volcanism along the ultraslow-spreading Southwest Indian Ridge. Nature Geoscience, 3(4): 286-292 Stein C A, Stein S. 1994. Constraints on hydrothermal heat flux through the oceanic lithosphere from the global heat flow. Journal of Geophysical Research, 99(B2): 3081-3195 Suo Yanhui. 2014. Tectonic-magmatic processes of the Indian Ocean: evidence on the residual mantle Bouguer gravity anomaly (in Chinese) [dissertation]. Qingdao: Ocean University of China Tao Chunhui, Li Huaiming, Jin Xiaobing, et al. 2014. Seafloor hydrothermal activity and polymetallic sulfide exploration on the southwest Indian ridge. Chinese Science Bulletin, 59(19): 2266-2276 Tao Chunhui, Lin Jian, Guo Shiqin, et al. 2012. First active hydrothermal vents on an ultraslow-spreading center: southwest Indian ridge. Geology, 40(1): 47-50 Tao Chunhui, Wu Tao, Jin Xiaobing, et al. 2013. Petrophysical characteristics of rocks and sulfides from the SWIR hydrothermal field. Acta Oceanologica Sinica, 32(12): 118-125 Tao Chunhui, Wu Guanghai, Ni Jianyu, et al. 2009. New hydrothermal fields found along the SWIR during the legs 5-7 of the Chinese DY115-20 Expedition. In: American Geophysical Union, Fall Meeting, Abstract OS21A-1150. Washington DC: American Geophysical Union Tivey M K. 2007. Generation of seafloor hydrothermal vent fluids and associated mineral deposits. Oceanography, 20(1): 50-65 Tivey M A, Dyment J. 2010. The magnetic signature of hydrothermal systems in slow spreading environments. In: Rona P A, Devey C W, Dyment J, et al., eds. Diversity of Hydrothermal Systems on Slow Spreading Ocean Ridges. Washington DC: American Geophysical Union, 43-66 Tucholke B E, Lin Jian, Kleinrock M C. 1998. Megamullions and mullion structure defining oceanic metamorphic core complexes on the Mid-Atlantic Ridge. Journal of Geophysical Research, 103(B5): 9857-9866 Vine F J, Moores E M. 1972. A model for the gross structure, petrology, and magnetic properties of oceanic crust. Geological Society of America Memoirs, 132: 195-206 Yao Huiqiang, Tao Chunhui, Song Chengbing, et al. 2011. Integration study on mode for seafloor plolymetallic sulfide exploration. Journal of Central South University: Science and Technology (in Chinese), 42(S2): 114-122 Zhang Tao, Gao Jinyao, Chen Mei. 2005. The reasonable correction of eötvös effect in marine gravity survey. Hydrographic Surveying and Charting, 25(2): 17-20 Zhang Tao, Lin Jian, Gao Jinyao. 2011. Interactions between hotspots and the Southwest Indian Ridge during the last 90 Ma: implications on the formation of oceanic plateaus and intra-plate seamounts. Science China: Earth Sciences, 54(8): 1177-1188 Zhang Tao, Lin Jian, Gao Jinyao. 2013. Magmatism and tectonic processes in Area A hydrothermal vent on the Southwest Indian Ridge. Science China: Earth Sciences, 56(12): 2186-2197 Zhao Minghui, Qiu Xuelin, Li Jiabiao, et al. 2013. Three-dimensional seismic structure of the Dragon Flag oceanic core complex at the ultraslow spreading Southwest Indian Ridge (49°39'E). Geochemistry, Geophysics, Geosystems, 14(10): 4544-4563 Zhou Huaiyang, Dick H J B. 2013. Thin crust as evidence for depleted mantle supporting the Marion Rise. Nature, 494(7436): 195-200
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