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Episodic Growth and Multiple Modification of Precambrian Lower Crust in the Southeastern Margin of North China Craton: Petrologic,Geochronological and Hf-isotopic Evidences(PDF)

《地球科学与环境学报》[ISSN:1672-6561/CN:61-1423/P]

Issue:
2012年第04期
Page:
1-11
Research Field:
基础地质与矿产地质
Publishing date:

Info

Title:
Episodic Growth and Multiple Modification of Precambrian Lower Crust in the Southeastern Margin of North China Craton: Petrologic,Geochronological and Hf-isotopic Evidences
Author(s):
LIU Yi-can12 WANG An-dong12
1. Key Laboratory of Crust-mantle Materials and Environments,Chinese Academy of Sciences,Hefei 230026, Anhui, China; 2. School of Earth and Space Sciences, University of Science and Technology of China, Hefei 230026, Anhui, China
Keywords:
zircon U-Pb geochronology Hf-isotope granulite-facies metamorphism lower crust episodic growth Precambrian North China Craton
PACS:
P588.3
DOI:
-
Abstract:
The early Precambrian is regarded to be a crucial stage for continental crust formation. The Precambrian lower-crustal rocks in the southeastern margin of North China Craton occur as the exposed metamorphic basement(named as the Wuhe metamorphic complex)and xenoliths in the Mesozoic dioritic to monzodioritic porphyry. These rocks provide an excellent natural laboratory to study formation and evolution of the Precambrian lower crust in the region. Integrated investigations on metamorphic petrology, petrologic geochemistry, Hf-isotope and zircon U-Pb geochronology of the rocks suggested that the Precambrian lower crust beneath the studied region experienced an episodic growth and multiple modification history. Intensive tectono-thermo events and metamorphic overprinting mainly occurred at several peaks, such as 2.5-2.6, 2.1, 1.8-1.9 Ga and 390, 176 Ma. For the 2.5-2.6 Ga lower-crustal rocks, some of them with high radiogenic Pb-isotopic compositions, which were similar to those formed at 2.1 Ga subduction-related arc setting and underwent 1.8 Ga high-pressure granulite-facies metamorphism, suffered from high-pressure granulite-facies metamorphism at 2.1 Ga and(or)1.8-1.9 Ga, and subsequent metamorphic overprinting at 390 Ma and 176 Ma; however, others had low radiogenic Pb-isotopic compositions for typical Precambrian lower-crustal rocks, and formed at 2.55-2.64 Ga and underwent 2.48-2.49 Ga peak metamorphism of granulite-facies without record of post-peak metamorphic overprint at 2.1 Ga and(or)1.8-1.9 Ga. Therefore, they formed simultaneously, but probably located at different crustal levels and escaped from subsequent metamorphic overprinting, strongly depending on their formation depths. The 2.7-2.8 Ga ages defined by inherited zircons and depleted mantle zircon-Hf model ages could record an earlier crustal growth episode in the area.

References:

[1] RUDNICK R L.Making Continental Crust[J].Nature,1995,378:571-578.
[2] WEBER M B I,TARNEY J,KEMPTON P D,et al.Crustal Make-up of the Northern Andes:Evidence Based on Deep Crustal Xenolith Suites,Mercaderes,SW Colombia[J].Tectonophysics,2002,345(1/2/3/4):49-82.
[3] KEMPTON P D,DOWNES H,EMBEY-ISZTIN A.Mafic Granulite Xenoliths in Neogene Alkali Basalts from the Western Pannonian Basin:Insight into the Lower Crust of a Collapsed Orogen[J].Journal of Petrology,1997,38(7):941-970.
[4] YARDLEY B W D.An Introduction to Metamorphic Petrology[M].London:Longman Scientific and Technical,1989.
[5] O'BRIEN P J,RÖTZLER J.High-pressure Granulites:Formation,Recovery of Peak Conditions,and Implications for Tectonics[J].Journal of Metamorphic Geology,2003,21(1):3-20.
[6] PATTISON D R M.Petrogenetic Significance of Orthopyroxene-free Garnet + Clinopyroxene + Plagioclase ± Quartz-bearing Metabasites with Respect to the Amphibolite and Granulite Facies[J].Journal of Metamorphic Geology,2003,21(1):21-34.
[7] INDARES A D.Metamorphic Textures and P-T Evolution of High-P Granulites from the Lelukuau Terrane,NE Grenville Province[J].Journal of Metamorphic Geology,2003,21(1):35-48.
[8] ZHAO G,WILDE S A,CAWOOD P A,et al.Archean Blocks and Their Boundaries in the North China Craton:Lithological,Geochemical,Structural,and P-T Path Constraints and Tectonic Evolution[J].Precambrian Research,2001,107(1/2):45-73.
[9] CARSWELL D A,O'BRIEN P J.Thermobarometry and Geotectonic Significance of High-pressure Granulites:Examples from the Moldanubian Zone of the Bohemian Massif in Lower Austria[J].Journal of Petrology,1993,34(3):427-459.
[10] ZHAO G C,CAWOOD P A,WILDE S A,et al.Metamorphism of Basement Rocks in the Central Zone of the North China Craton:Implications for Palaeoproterozoic Tectonic Evolution[J].Precambrian Research,2000,103(1/2):55-88.
[11] ZHAO G C,WILDE S A,CAWOOD P A,et al.Archean Blocks and Their Boundaries in the North China Craton:Lithological,Geochemical,Structural,and P-T Path Constraints and Tectonic Evolution[J].Precambrian Research,2001,107(1/2):45-73.
[12] GUO J H,O'BRIEN P J,ZHAI M G.High-pressure Granulites in the Sanggan Area,North China Craton:Metamorphic Evolution,P-T Paths and Geotectonic Significance[J].Journal of Metamorphic Geology,2002,20(8):741-756.
[13] GUO J H,SUN M,CHEN F K,et al.Sm-Nd and SHRIMP U-Pb Zircon Geochronology of High-pressure Granulites in the Sanggan Area,North China Craton:Timing of Paleoproterozoic Continental Collision[J].Journal of Asian Earth Sciences,2005,24(5):629-642.
[14] WILDE S A,ZHAO G C,SUN M.Development of the North China Craton During the Late Archaean and Its Final Amalgamation at 1.8 Ga:Some Speculations on Its Position Within a Global Palaeoproterozoic Supercontinent[J].Gondwana Research,2002,5(1):85-94.
[15] KRÖNER A,WILDE S A,LI J H,et al.Age and Evolution of a Late Archean to Paleoproterozoic Upper to Lower Crustal Section in the Wutaishan/Hengshan/Fuping Terrain of Northern China[J].Journal of Asian Earth Sciences,2005,24(5):577-595.
[16] WILDE S A,ZHAO G C.Archean to Paleoproterozoic Evolution of the North China Craton[J].Journal of Asian Earth Sciences,2005,24(5):519-522.
[17] HOU G T,LIU Y L,LI J H.Evidence for ~1.8 Ga Extension of the Eastern Block of the North China Craton from SHRIMP U-Pb Dating of Mafic Dyke Swarms in Shandong Province[J].Journal of Asian Earth Sciences,2006,27(4):392-401.
[18] ZHAI M G,BIAN A G,ZHAO T P.The Amalgamation of the Supercontinent of North China Craton at the End of the Neo-archaean,and Its Breakup During the Late Palaeoproterozoic and Meso-proterozoic[J].Science in China:Series D,2000,43(S):219-232.
[19] ZHAI M G,LIU W J.Palaeoproterozoic Tectonic History of the North China Craton:A Review[J].Precambrian Research,2003,122(1/2/3/4):183-199.
[20] PENG P,ZHAI M G,ZHANG H F,et al.Geochronological Constraints on the Paleoproterozic Evolution of the North China Craton:SHRIMP Zircon Ages of Different Types of Mafic Dikes[J].International Geology Review,2005,47(5):492-508.
[21] HOU G T,LI J H,YANG M H,et al.Geochemical Constraints on the Tectonic Environment of the Late Palaeoproterozoic Mafic Dyke Swarms in the North China Craton[J].Gondwana Research,2008,13(1):103-116.
[22] LU S N,ZHAO G C,WANG H C,et al.Precambrian Metamorphic Basement and Sedimentary Cover of the North China Craton:A Review[J].Precambrian Research,2008,160(1/2):77-93.
[23] ZHAI M G,GUO J H,YAN Y H,et al. Discovery of High-pressure Basic Granulite Terrain in North China Archaean Craton and Preliminary Study[J].Science in China:Series B,1993,36(11):1402-1408.
[24] ZHENG J P,SUN M,LU F X,et al.Mesozoic Lower Crustal Xenoliths and Their Significance in Lithospheric Evolution Beneath the Sino-Korean Craton[J].Tectonophysics,2003,361(1/2):37-60.
[25] XU W L,WANG D Y,LIU X C,et al.Discovery of Eclogite Inclusions and Its Geological Significance in Early Jurassic Intrusive Complex in Xuzhou-northern Anhui,Eastern China[J].Chinese Science Bulletin,2002,47(14):1212-1216.
[26] XU W L,GAO S,WANG Q H,et al.Mesozoic Crustal Thickening of the Eastern North China Craton:Evidence from Eclogite Xenoliths and Petrologic Implications[J].Geology,2006,34(9):721-724.
[27] XU W L,GAO S,YANG D B,et al.Geochemistry of Eclogite Xenoliths in Mesozoic Adakitic Rocks from Xuzhou-Suzhou Area in Central China and Their Tectonic Implications[J].Lithos,2009,107(3/4):269-280.
[28] GUO S S,LI S G.SHRIMP Zircon U-Pb Ages for the Palaeoproterozoic Metamorphic-magmatic Events in the Southeast Margin of the North China Craton[J].Science in China:Series D,2009,52(8):1039-1045.
[29] LIU Y C,WANG A D,ROLFO F,et al.Geochronological and Petrological Constraints on Palaeoproterozoic Granulite Facies Metamorphism in Southeastern Margin of the North China Craton[J].Journal of Metamorphic Geology,2009,27(2):125-138.
[30] LIU D Y,NUTMAN A P,COMPSTON W,et al.Remnants of ≥3 800 Ma Crust in Chinese Part of the Sino-Korean Craton[J].Geology,1992,20(4):339-342.
[31] KUSKY T M,LI J H.Paleoproterozoic Tectonic Evolution of the North China Craton[J].Journal of Asian Earth Sciences,2003,22(4):383-397.
[32] WANG A D,LIU Y C,SANTOSH M,et al.Zircon U-Pb Geochronology,Geochemistry and Sr-Nd-PbIsotopes from the Metamorphic Basement in the Wuhe Complex:Implications for Neoarchean Active Continental Margin Along the Southeastern North China Craton and Constraints on the Petrogenesis of Mesozoic Granitoids[J].Geoscience Frontiers,2012,doi:10.1016/j.qsf.2012.05.001.
[33] LIU Y C,WANG A D,LI S G,et al.Composition and Geochronology of the Deep-seated Xenoliths from the Southeastern Margin of the North China Craton[J].Gondwana Research,2012,doi:10.1016/j.gr.2012.06.009.
[34] WANG A D,LIU Y C,GU X F,et al.Late-Neoarchean Magmatism and Metamorphism at the Southeastern Margin of the North China Craton and Their Tectonic Implications[J].Precambrian Research,2012,220/221:65-79.
[35] 王安东,刘贻灿,古晓锋,等.蚌埠老山含石榴子石片麻状花岗岩的锆石SHRIMP U-Pb年龄及其对华南俯冲陆壳再循环的意义[J].矿物岩石,2009,29(2):38-43. WANG An-dong,LIU Yi-can,GU Xiao-feng,et al.Zircon SHRIMP U-Pb Dating for Garnet-bearing Gneissic Granite at Laoshan,Bengbu:Implications for Recycling of the Subducted Continental Crust of the South China Block[J].Journal of Mineralogy and Petrology,2009,29(2):38-43.
[36] YANG D B,XU W L,WANG Q H,et al.Chronology and Geochemistry of Mesozoic Granitoids in the Bengbu Area,Central China:Constraints on the Tectonic Evolution of the Eastern North China Craton[J].Lithos,2010,114(1/2):200-216.
[37] LEAKE B E,WOOLLEY A R,ARPS C E S,et al.Nomenclature of Amphiboles:Report of the Subcommittee on Amphiboles of the International Mineralogical Association,Commission on New Minerals and Mineral Names[J].American Mineralogist,1997,82(9/10):1019-1037.
[38] RAASE P.Al and Ti Contents of Hornblende,Indicators of Pressure and Temperature of Regional Metamorphism[J].Contributions to Mineralogy and Petro-logy,1974,45(3):231-236.
[39] GROPPO C,LOMBARDO B,ROLFO F,et al.Clockwise Exhumation Path of Granulitized Eclogites from the Ama Drime Range(Eastern Himalayas)[J].Journal of Metamorphic Geology,2007,25(1):51-75.
[40] ROGERS N W.Granulite Xenoliths from Lesotho Kim-berlites and the Lower Continental Crust[J].Nature,1977,270:681-684.
[41] DESSAI A G,MARKWICK A,VASELLI O,et al.Granulite and Pyroxenite Xenoliths from the Deccan Trap:Insight into the Nature and Composition of the Lower Lithosphere Beneath Cratonic India[J].Lithos,2004,78(3):263-290.
[42] FROST B R,CHACKO T.The Granulite Uncertainty Principle:Limitations on Thermobarometry in Granulites[J].The Journal of Geology,1989,97(4):435-450.
[43] DAVIS W J,CANIL D,MACKENZIE J M,et al.Petrology and U-Pb Geochronology of Lower Crustal Xenoliths and the Development of a Craton,Slave Province,Canada[J].Lithos,2003,71(2):541-573.
[44] CHERNIAK D J,WATSON E B.Diffusion in Zircon[J].Reviews in Mineralogy and Geochemistry,2003,53(1):113-143.
[45] RUBATTO D,WILLIAMS I S,BUICK I S.Zircon and Monazite Response to Prograde Metamorphism in the Reynolds Range,Central Australia[J].Contributions to Mineralogy and Petrology,2001,140(4):458-468.
[46] AYERS J C,DUNKLE S,GAO S,et al.Constraints on Timing of Peak and Retrograde Metamorphism in the Dabie Shan Ultrahigh-pressure Metamorphic Belt,East-central China,Using U-Th-Pb Dating of Zircon and Monazite[J].Chemical Geology,2002,186(3/4):315-331.
[47] MÖLLER A,O'BRIEN P J,KENNEDY A,et al.Polyphase Zircon in Ultrahigh-temperature Granulites(Rogaland,SW Norway):Constraints for Pb Diffusion in Zircon[J].Journal of Metamorphic Geology,2002,20(8):727-740.
[48] LIU Y C,LI S G,GU X F,et al.Ultrahigh-pressure Eclogite Transformed from Mafic Granulite in the Dabie Orogen,East-central China[J].Journal of Metamorphic Geology,2007,25(9):975-989.
[49] LIU Y C,GU X F,LI S G,et al.Multistage Metamorphic Events in Granulitized Eclogites from the North Dabie Complex Zone,Central China:Evidence from Zircon U-Pb Age,Trace Element and Mineral Inclusion[J].Lithos,2011,122(1/2):107-121.
[50] CORFU F,HANCHAR J M,HOSKIN P W O,et al.Altas of Zircon Textures[J].Reviews in Mineralogy md Geochemistry,2003,53(1):469-500.
[51] GEBAUER D,SCHERTL H P,BRIX M,et al.35 Ma Old Ultrahigh-pressure Metamorphism and Evidence for Very Rapid Exhumation in the Dora Maira Massif,Western Alps[J].Lithos,1997,41(1/2/3):5-24.
[52] HERMANN J,RUBATTO D,KORASKOV A,et al.Multiple Zircon Growth During Fast Exhumation of Diamondiferous,Deeply Subducted Continental Crust(Kokchetav Massif,Kazakhstan)[J].Contributions to Mineralogy and Petrology,2001,141(1):66-82.
[53] AMELIN Y,LEE D C,HALLIDAY A N.Early-middle Archaean Crustal Evolution Deduced from Lu-Hf and U-Pb Isotopic Studies of Single Zircon Grains[J].Geochimica et Cosmochimica Acta,2000,64(24):4205-4225.
[54] GERDES A,ZEH A.Zircon Formation Versus Zircon Alteration—New Insights from Combined U-Pb and Lu-Hf In-situ LA-ICP-MS Analyses,and Consequences for the Interpretation of Archean Zircon from the Central Zone of the Limpopo Belt[J].Chemical Geology,2009,261(3/4):230-243.
[55] GRIFFIN W L,BELOUSOVA E A,SHEE S R,et al.Archean Crustal Evolution in the Northern Yilgarn Craton:U-Pb and Hf-isotope Evidence from Detrital Zircons[J].Precambrian Research,2004,131(3/4):231-282.
[56] WOODHEAD J,HERGT J,SHELLEY M,et al.Zircon Hf-isotope Analysis with an Excimer Laser,Depth Profiling,Ablation of Complex Geometries,and Concomitant Age Estimation[J].Chemical Geology,2004,209(1/2):121-135.
[57] VERVOORT J D,BLICHERT-TOFT J.Evolution of the Depleted Mantle:Hf Isotope Evidence from Juvenile Rocks Through Time[J].Geochimica et Cosmochimica Acta,1999,63(3/4):533-556.
[58] GRIFFIN W L,PEARSON N J,BELOUSOVA E,et al.The Hf Isotope Composition of Cratonic Mantle:LAM-MC-ICPMS Analysis of Zircon Megacrysts in Kimberlites[J].Geochimica et Cosmochimica Acta,2000,64(1):133-147.
[59] ANDERSEN T,GRIFFIN W L,PEARSON N J.Crustal Evolution in the SW Part of the Baltic Shield:the Hf Isotope Evidence[J].Journal of Petrology,2002,43(9):1725-1747.
[60] CONDIE K C,BEYER E,BELOUSOVA E,et al.U-Pb Isotopic Ages and Hf Isotopic Composition of Single Zircons:The Search for Juvenile Precambrian Continental Crust[J].Precambrian Research,2005,139(1/2):42-100.
[61] IIZUKA T,HIRATA T,KOMIYA T,et al.U-Pb and Lu-Hf Isotope Systematics of Zircons from the Mississippi River Sand:Implications for Reworking and Growth of Continental Crust[J].Geology,2005,33(6):485-488.
[62] HAWKESWORTH C J,KEMP A I S.Using Hafnium and Oxygen Isotopes in Zircons to Unravel the Record of Crustal Evolution[J].Chemical Geology,2006,226(3/4):144-162.
[63] WU F Y,YANG Y H,XIE L W,et al.Hf Isotopic Compositions of the Standard Zircons and Baddeleyites Used in U-Pb Geochronology[J].Chemical Geology,2006,234(1/2):105-126.
[64] KEMP A I S,FOSTER G L,SCHERSTEN A,et al.Concurrent Pb-Hf Isotope Analysis of Zircon by Laser Ablation Multi-collector ICP-MS,with Implications for the Crustal Evolution of Greenland and the Himalayas[J].Chemical Geology,2009,261(3/4):244-260.
[65] ZEH A,GERDES A,BARTON J M,et al.Archean Accretion and Crustal Evolution of the Kalahari Craton—The Zircon Age and Hf Isotope Record of Granitic Rocks from Barberton/Swaziland to the Francistown Arc[J].Journal of Petrology,2009,50(5):933-966.
[66] HUANG X L,XU Y G,LIU D Y.Geochronology,Petrology and Geochemistry of the Granulite Xenoliths from Nushan,East China:Implication for a Heterogeneous Lower Crust Beneath the Sino-Korean Craton[J].Geochimica et Cosmochimica Acta,2004,68(1):127-149.
[67] ZHENG J P,GRIFFIN W L,MA Q,et al.Accetion and Reworking Beneath the North China Craton[J].Lithos,2012,149(1):61-78.

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