Journal of Jilin University(Earth Science Edition) ›› 2019, Vol. 49 ›› Issue (2): 414-424.doi: 10.13278/j.cnki.jjuese.20170127

Previous Articles     Next Articles

Recognition of Subduction Melt and Fluid Component in Lau and Manus Basins: Sr-Nd-Pb Isotope Ratios and Independent Component Analysis

Wu Xichang, Chu Fengyou, Wang Wei, Li Zhenggang, Chen Ling, Bi Dongwei, Wang Jianqiang   

  1. Key Laboratory of Submarine Geoscience/Second Institute of Oceanography, State Oceanic Administration(SOA), Hangzhou 310012, China
  • Received:2018-12-28 Online:2019-03-26 Published:2019-03-28
  • Supported by:
    Supported by National Key Basic Research Program ("973" Program) of China (2013CB429705, 2013CB429701), Natural Science Foundation of Zhejiang Province (LQ17D060005,LQ17D060004) and Scientific Research Fund of the Second Institute of Oceanography, SOA (JG1605,JG1603,JG1410).

PDF (PC)

356

Abstract: The effects of subducted sediments and altered oceanic crust (AOC) on back-arc magmatism were studied using independent component analysis on multi-isotope dataset. Sr-Nd-Pb isotope data of magmatic rocks from Lau and Manus basins, as well as the Pacific and Indian oceanic ridges, were analyzed, and five independent components (ICs) were identified. The negative correlation between IC1 and 87Sr/86Sr and Th/Nb suggests that the IC1 represents the influence of hydrous melt derived from subducted sediments on the sub-arc mantle, and can be used to distinguish back-arc basin from mid-ocean ridge settings. The negative correlation between IC5 and Ba/Th suggests that IC5 may reflect the influence of aqueous fluid derived from the AOC on the sub-arc mantle. Furthermore, the correlation between IC5 and Th/U indicates that the IC5 values may be related to the age of recycled oceanic crust in the mantle. A comparison between the IC1 and IC5 values of Lau and Manus basins shows that the eastern rift (ER) of Manus basin exhibits similar IC5 but lower IC1 relative to that of Lau basin, whereas the manus spreading center (MSC) and extensional transform zone (ETZ) of Manus basin show similar IC1 but higher IC5 compared with that of Lau basin. These differences suggest that the influences of sediment melts are the strongest in the ER, while AOC fluid exerts similar influence on ER and Lau basin, but much less on MSC and ETZ. We believe that the difference in the degree of sediment melt influence may be associated with variable sediment thickness being subducted into the New Britain and Tonga trenches, while the extent of AOC fluid influence is controlled by the distance of back-arc ridges away from the trench.

Key words: independent component analysis, back-arc basin, Sr-Nd-Pb isotope, altered oceanic crust, subducted sediment, Lau basin, Manus basin

CLC Number: 

  • P597
[1] Beier C,Turner S P,Sinton J M,et al.Influence of Subducted Components on Back-Arc Melting Dynamics in the Manus Basin[J].Geochemistry Geophysics Geosystems,2010,11(6):1-21.doi:10.1029/2010GC003037.
[2] Class C,Miller D M,Goldstein S L,et al. Distinguishing Melt and Fluid Subduction Components in Umnak Volcanics,Aleutian Arc[J].Geochemistry Geophysics Geosystems,2000,1(6):927-928.
[3] Elliott T,Plank T,Zindler A,et al. Element Transport from Slab to Volcanic Front at the Mariana Arc[J].Journal of Geophysical Research Atmospheres,1997,1021:14991-15020.
[4] Plank T,Langmuir C H.The Chemical Composition of Subducting Sediment and Its Consequences for the Crust and Mantle[J].Chemical Geology,1998,145:325-394.
[5] Pearce J A,Stern R J.Origin of Back-Arc Basin Magmas:Trace Element and Isotope Perspectives[J].Washington Dc American Geophysical Union Geophysical Monograph,2006,166:63-86.
[6] Pearce J A,Stern R J,Bloomer S H,et al.Geochemical Mapping of the Mariana Arc-Basin System:Implications for the Nature and Distribution of Subduction Components[J].Geochemistry Geophysics Geosystems,2005,6(7):406-407.
[7] Sinton J M,Ford L L,Chappell B,et al.Magma Genesis and Mantle Heterogeneity in the Manus Back-Arc Basin,Papua New Guinea[J].Journal of Petrology,2003,44(1):159-195.
[8] Volpe A M,Macdougall J D,Hawkins J W.Mariana Trough Basalts (MTB):Trace Element and Sr Nd Isotopic Evidence for Mixing Between MORB-Like and Arc-Like Melts[J]. Earth & Planetary Science Letters,1987,82(3):241-254.
[9] Volpe A M,Macdougall J D,Lugmair G W,et al.Fine-Scale Isotopic Variation in Mariana Trough Basalts:Evidence for Heterogeneity and a Recycled Component in Backarc Basin Mantle[J]. Earth & Planetary Science Letters,1990,100(1):251-264.
[10] Manning C E.The Chemistry of Subduction-Zone Fluids[J].Earth & Planetary Science Letters,2004,223(1/2):1-16.
[11] Hermann J,Spandler C J.Sediment Melts at Sub-Arc Depths:An Experimental Study[J].Journal of Petrology,2008,49(4):717-740.
[12] Stolper E,Newman S.The Role of Water in the Petrogenesis of Mariana Trough Magmas[J]. Earth & Planetary Science Letters,1994,121:293-325.
[13] Iwamori H,Albarède F.Decoupled Isotopic Record of Ridge and Subduction Zone Processes in Oceanic Basalts by Independent Component Analysis[J].Geochemistry Geophysics Geosystems,2008,9(4):366-389.
[14] Iwamori H,Albaréde F,Nakamura H.Global Structure of Mantle Isotopic Heterogeneity and Its Implications for Mantle Differentiation and Convection[J].Earth & Planetary Science Letters,2010,299(3):339-351.
[15] Iwamori H,Nakamura H.East-West Geochemical Hemispheres Constrained from Independent Component Analysis of Basalt Isotopic Compositions[J].Geochemical Journal,2012,46(4):39-46.
[16] Iwamori H,Nakamura H.Isotopic Heterogeneity of Oceanic Arc and Continental Basalts and Its Implications for Mantle Dynamics[J].Gondwana Research,2015,27(3):1131-1152.
[17] Yasukawa K,Nakamura K,Fujinaga K,et al.Tracking the Spatiotemporal Variations of Statistically Independent Components Involving Enrichment of Rare-Earth Elements in Deep-Sea Sediments[J]. Scientific Reports,2016,6:29603.
[18] Martinez F,Taylor B. Mantle Wedge Control on Back-Arc Crustal Accretion.[J].Nature,2002,416:417-420.
[19] Taylor B.Bismarck Sea:Evolution of the Back-Arc Basin[J]. Geology,1979,7(4):1190.
[20] Taylor B,Crook K,Sinton J.Extensional Transform Zones and Oblique Spreading Centers[J].Journal of Geophysical Research Solid Earth,1994,99(B10):19707-19718.
[21] Yang J,Cheng Q.A Comparative Study of Independent Component Analysis with Principal Component Analysis in Geological Objects Identification:Part Ⅱ:A Case Study of Pinghe District,Fujian,China[J].Journal of Geochemical Exploration,2015,149:136-146.
[22] Othman D B,White W M,Patchett J.The Geochemistry of Marine Sediments,Island Arc Magma Genesis,and Crust-Mantle Recycling[J].Earth & Planetary Science Letters,1989,94:1-21.
[23] Dupré B,Allègre C J.Pb-Sr Isotope Variation in Indian Ocean Basalts and Mixing Phenomena[J].Nature,1983,303:142-146.
[24] Mper M R,Hofmann A W.Recycled Ocean Crust and Sediment in Indian Ocean MORB[J].Earth & Planetary Science Letters,1997,147:93-106.
[25] Brenan J M,Shaw H F,Ryerson F J,et al.Mineral-Aqueous Fluid Partitioning of Trace Elements at 900℃ and 2.0 GPa:Constraints on the Trace Element Chemistry of Mantle and Deep Crustal Fluids[J].Geochimica et Cosmochimica Acta,1995,59(16):3331-3350.
[26] Hart S R.The DUPAL Anomaly:A Large-Scale Isotopic Anomaly in the Southern Hemisphere[J].Nature,1984,309:753-757.
[27] Elliott T,Zindler A,Bourdon B.Exploring the Kappa Conundrum:The Role of Recycling in the Lead Isotope Evolution of the Mantle[J].Earth & Planetary Science Letters,1999,169:129-145.
[28] Hanyu T,Dosso L,Ishizuka O,et al.Geochemical Diversity in Submarine HIMU Basalts from Austral Islands,French Polynesia[J].Contributions to Mineralogy and Petrology,2013,166(5):1285-1304.
[29] Hanyu T,Kawabata H,Tatsumi Y,et al.Isotope Evolution in the HIMU Reservoir Beneath St.Helena:Implications for the Mantle Recycling of U and Th[J]. Geochimica et Cosmochimica Acta,2014,143(1):232-252.
[30] Whitmore G P,Crook K A W,Johnson D P.Sedimentation in a Complex Convergent Margin:The Papua New Guinea Collision Zone of the Western Solomon Sea[J].Marine Geology,1999,157:19-45.
[1] Yin Zhengxin, Li Zhengyuan, Shen Zezhong, Tang Minqiang, Wei Wei, Liu Qiang, Xie Mingrui, Cai Zhourong. Asymmetric Geological Developments and Their Geneses of the Parece Vela Basin in Western Pacific Ocean [J]. Journal of Jilin University(Earth Science Edition), 2019, 49(1): 218-229.
[2] Wu Jianhua, Xie Kairui, Zhu Hongtao, Wu Rengui, Liu Shuai. Petrogenesis of Rhyolite from Hongshanzi Basin in Southern Greater Xing'an Range: Elements and Sr-Nd-Pb Isotope Constraints [J]. Journal of Jilin University(Earth Science Edition), 2016, 46(6): 1724-1739.
[3] Shi Xuefa, Li Bing, Yan Quanshu, Ye Jun. Hydrothermal Activities and Mineralization in the Arc and Back-Arc Basin Systems, Western Pacific [J]. Journal of Jilin University(Earth Science Edition), 2016, 46(4): 1124-1138.
[4] Li Wei, Xie Guiqing, Yao Lei, Zhu Qiaoqiao, Sun Hongtao, Wang Jian, Wang Xiaoyu. Genesis of the Intrusive Rocks in the Chengchao Large Skarn Iron Deposit, Southeastern Hubei Province [J]. Journal of Jilin University(Earth Science Edition), 2014, 44(6): 1827-1855.
[5] YU Xian-chuan, LIU Li-wen, HU Dan, WANG Zhong-ni. Robust Ordinal Independent Component Analysis(ROICA) Applied to Mineral Resources Prediction [J]. J4, 2012, 42(3): 872-880.
[6] LEI Ji-jiang, CHU Feng-you, XU Xiao-guo, LI Xiao-hu, YAO Chun-hui, YANG Ke-hong. Micro-Area Characteristics and Implications of Hydrothermal Plume-Derived Particles in Lau Basin [J]. J4, 2011, 41(2): 432-439.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Copyright © Journal of Jilin University(Earth Science Edition), All Rights Reserved.
Tel: +86-431-88502374;13756165364 E-mail: xuebao1956@jlu.edu.cn
Powered by Beijing Magtech Co. Ltd