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黄金科学技术 ›› 2024, Vol. 32 ›› Issue (2): 220-240.doi: 10.11872/j.issn.1005-2518.2024.02.124

• 矿产勘查与资源评价 • 上一篇    下一篇

滇西古近纪钾质—超钾质岩浆岩成岩成矿作用及构造意义

全海辉1(),柴鹏1(),袁玲玲1,焦守涛2   

  1. 1.中国地质科学院地质研究所,北京 100037
    2.中国地质调查局自然资源综合调查指挥中心,北京 100055
  • 收稿日期:2023-09-05 修回日期:2024-03-04 出版日期:2024-04-30 发布日期:2024-05-21
  • 通讯作者: 柴鹏 E-mail:jennyq0429@163.com;cx001chaipeng@163.com
  • 作者简介:全海辉(2000-),男,广西桂林人,硕士研究生,从事铜金矿勘查研究工作。jennyq0429@163.com
  • 基金资助:
    国家重点研发计划项目专题“青藏高原典型地区深部新老地壳物质架构示踪方法”(2019YFA0708602);中国地质科学院基本科研业务费项目“深地实验室重点攻关项目”(JKYZD202312);国家自然科学基金项目“吉林延吉地区闹枝中硫化型浅成低温热液金—多金属矿床成矿过程精细刻画”(41973045)

Petrogenesis Mineralization and Tectonic Implications of Paleoproterozoic Potassic-Ultrapotassic Magmatic Rocks in Western Yunnan

Haihui QUAN1(),Peng CHAI1(),Lingling YUAN1,Shoutao JIAO2   

  1. 1.Institute of Geology, Chinese Academy of Geological Sciences, Beijing 100037, China
    2.Natural Resources Comprehensive Survey Command Center, China Geological Survey, Beijing 100055, China
  • Received:2023-09-05 Revised:2024-03-04 Online:2024-04-30 Published:2024-05-21
  • Contact: Peng CHAI E-mail:jennyq0429@163.com;cx001chaipeng@163.com

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摘要:

滇西地区广泛发育古近纪钾质—超钾质岩浆岩,形成沿金沙江—哀牢山断裂带富碱岩浆岩带,因缺乏对该钾质—超钾质岩浆岩带的系统研究,岩石成因及其与成矿之间的关系尚存在诸多争论。通过收集该富碱岩浆岩带已发表的全岩主微量元素、Sr-Nd同位素、锆石Hf同位素及年代学数据,根据构造位置,将该岩带划分为南、中、北岩带3个部分。通过系统对比分析得出:滇西古近纪钾质—超钾质岩浆岩成岩年龄基本一致,峰值为35 Ma,为同一期构造热事件的产物;基性—超基性和中酸性岩类具有不同成因,前者富集大离子亲石元素(LILE),亏损高场强元素(HFSE),高(87Sr/86Sr) i 比值,低εNdt)值,可能来源于板片交代的富集岩石圈地幔,后者具有较高的SiO2含量,可能为壳幔混合的产物;基性—超基性和中酸性岩类的形成均与金沙江—哀牢山断裂的剪切走滑和拉伸作用相关,是同一构造热事件下岩石圈不同深度部分熔融的产物;南中岩带钾质—超钾质岩浆岩与斑岩型金—(铜—钼)矿床关系密切,其岩浆形成过程可能为成矿提供了高氧逸度和含水量的有利条件,以及成矿物质和成矿流体。

关键词: 滇西, 钾质—超钾质岩, 岩石成因, 成矿作用, 新生下地壳, 新生代

Abstract:

The Paleoproterozoic potassic-ultrapotassic magmatic rocks are widely developed in western Yunnan,forming an alkali-rich magmatic rock belt along the Jinshajiang-Ailaoshan fracture zone.Due to the lack of systematic research on these potassic-ultrapotassic magmatic rocks,there are still many debates on the petrogenesis and their relationship with mineralization.In this paper,through the collection of published whole-rock major and trace element,Sr-Nd isotope,zircon Hf isotope and geochronology data of the whole rock in the alkali-rich magmatic belt,the rock belt is divided into three parts,namely,south,central and north rock belts according to the tectonic position.Through systematic comparative analysis,it is concluded that the diagenetic age of Paleoproterozoic potassic-ultrapotassic rock formation in western Yunnan is basically the same,with a peak value of 35 Ma,which is the product of the same period of tectonic thermal events.The basic-ultramafic and intermediate-acid rocks have different genesis.The former enriched in LILEs,deficit HFSEs,high (87Sr/86Sr) i,and low εNdt) values,probably originating from a slab-accounted enriched lithospheric mantle.The latter may be the product of crust-mantle mixing due to its higher SiO2 content.The formation of both is related to the shear slip and tensile action of the Jinshajiang-Ailaoshan fault,which is the product of partial melting of the lithosphere at different depths under the same tectonic thermal event.The potassic-ultrapotassic rocks of the southern and central rock belts are closely related to porphyry Au-(Cu-Mo) deposits.The magmatic formation process may provide favorable conditions for mineralization with high oxygen fugacity and water content,as well as ore-forming materials and ore-forming fluids.

Key words: western Yunnan, potassic-ultrapotassic magmatic rocks, petrogenesis, mineralization, Junior lower crust, Cenozoic

中图分类号: 

  • P611

图1

金沙江—哀牢山断裂带古近纪钾质—超钾质岩浆岩分布图(a)三江地区构造格架简图(修改自李勇等,2011);(b)扬子克拉通西部和思茅地块构造格架图(修改自Huang et al.,2010;武精凯等,2019;Xu et al.,2023); 1.新生代镁铁质熔岩;2.新生代中酸性侵入岩;3.新生代煌斑岩;4.片麻岩;5.火山岩;6.断裂;7.典型矿床;8.城市"

图2

滇西地区古近纪钾质—超钾质岩浆岩年龄统计分布图(年龄数据见附表1)"

表1

滇西地区古近纪钾质—超钾质岩浆岩数据统计"

数据类型数据量/组
中岩带南岩带合计
年龄563086
主微量452407859
Sr-Nd同位素106110216
Lu-Hf同位素402160562
Pb同位素352560
S同位素163753

图3

滇西地区古近纪钾质—超钾质岩浆岩Harker图解(数据来源见附表1)"

图4

滇西地区古近纪钾质—超钾质岩浆岩硅—碱图(底图据Le Maitre,2002;数据来源见附表1)"

图5

滇西地区古近纪钾质—超钾质岩浆岩硅—钾图(底图据Rickwood,1989;数据来源见附表1)"

图6

滇西地区古近纪钾质—超钾质岩浆岩钾—钠图(底图据Le Maitre,2002;数据来源见附表1)"

图7

滇西地区古近纪钾质—超钾质岩浆岩LREE/HREE与La/Yb比值图解(数据来源见附表1)"

图8

滇西地区古近纪钾质—超钾质岩浆岩(87Sr/86Sr) i -εNd(t)图解(底图据Lu et al.,2013a;数据来源见附表1)"

图9

滇西地区古近纪钾质—超钾质岩浆岩单颗锆石年龄与εHf(t)分布图(数据来源见附表1)"

图10

滇西古近纪矿石与不含矿岩石样品Pb同位素及S同位素图解(a)207Pb/204Pb-206Pb/204Pb图解;(b)208Pb/204Pb-206Pb/204Pb图解;(c)不同矿床S同位素组成图解;(d)不同矿床矿石黄铁矿S同位素直方图[Pb和S数据点来源见附表1;滇西钾质火山岩引自He et al.,2016;地幔源区储库见Zindler et al.,1986;北半球参考线(NHRL)数据见Hart,1984;大洋中脊玄武岩(MORB)数据见Guo et al.,2005;S同位素花岗岩数据见Hoefs,1997;其他端元数据见Seal,2006]"

图11

滇西地区古近纪钾质—超钾质岩浆岩成岩—成矿模式图(修改自Lu et al.,2013a;Xin et al.,2019;Xu et al.,2021)"

附表1

滇西地区古近纪钾质—超钾质岩浆岩数据来源列表"

序号数据类型数据来源
1年龄2、3、5、10、12、13、15~19、21、26、29、36、40、42、44、47、50、53、58、63、67
2主微量1~7、9~32、34~36、38~50、52~54、56~64、66~70
3稀土元素1~7、9、10、12~27、29~31、34~36、38~50、53、54、56~64、66~70
4Nd2、5、7、10、13~17、19、22、24~26、30、34、36、39、43、47、48、57、67、70
5Hf2、3、7、9、15、16、19、21、25、29、63、67、68
6Pb2、7、11、17、26、45、51、55、57
7S8、11、26、32、33、37、38、65
Bao X S, He W Y, Mao J W,et al,2023.Redox states and genesis of Cu- and Au-mineralized granite porphyries in the Jinshajiang Cu-Au metallogenic belt,SW China:Studies on the zircon chemistry[J].Mineral Deposita,58:1123-1142.
Bao Xinshang, He Wenyan, Gao Xue,2017.The Beiya gold deposit:Constraint from water-rich magmas to mineralization[J].Acta Petrologica Sinica,33(7):2175-2188.
Bi Xianwu, Hu Ruizhong, Cornell D H,2001.Trace element and isotope evidence for the evolution of ore-forming fluid of Yao’an gold deposit,Yunnan Province,China[J].Geochimica,30(3):264-272.
Bi Xianwu, Hu Ruizhong, Peng Jiantang,et al,2005.Geochemical characteristics of the Yao’an and Machangqing alkaline-rich instrusions[J].Acta Petrologica Sinica,21(1):115-126.
Bi Xianwu, Hu Ruizhong, Ye Zaojun,et al,1999.Study on the relationship between A-type granites and copper mineralization:A case study in Machangqing deposit[J].Science in China (Series D),29(6):489-495.
Cai Xinping,1992.Discover of deep-derived xenoliths in Cenozoic alkali-rich prophries along the margin of the Yangtze platform and its significance[J].Chinese Journal of Geology (Scientia Geologica Sinica),(2):183-189.
Campbell I H, Stepanov A S, Liang H Y,et al,2014.The origin of shoshonites:New insights from the Tertiary high-potassium intrusions of eastern Tibet[J].Contributions to Mineralogy and Petrology,167(3):1-22.
Chai P, Hou Z Q, Zhang H R,et al,2019.Geology,fluid inclusion and H-O-S-Pb isotope constraints on the mineralization of the Xiejiagou gold deposit in Jiaodong Peninsula[J].Geofluids,2019:3726465.
Chai P, Sun J G, Hou Z Q,et al,2016.Geological,fluid inclusion,H-O-S-Pb isotope,and Ar-Ar geochronology constraints on the genesis of the Nancha gold deposit,southern Jilin Province,northeast China[J].Ore Geology Reviews,72:1053-1071.
Chaussidon M, Lorand J P,1990.Sulphur isotope composition of orogenic spinel herzolite massifs from Ariege(North-Eastern Pyrenees,France):Anion microprobe study[J].Geochimica et Cosmochimica Acta,54(10):2835-2846.
Chu Yating,2016.Evolution of Fluids in Deep Processes,Petrogenesis and Metallogenesis of Cenozic Alkaline-rich Magma in Western Yunnan Province[D].Chengdu:Chengdu University of Technology.
Chung S L, Chu M F, Zhang Y Q,et al,2005.Tibetan tectonic evolution inferred from spatial and temporal variations in post-collisional magmatism[J].Earth-Science Reviews,68(3/4):173-196.
Chung S L, Lo C H, Lee T Y,et al,1998.Diachronous uplift of the Tibetan plateau starting 40? Myr ago[J].Nature,394(6695):769-773.
Deng J, Wang Q F, Li G J,et al,2014.Cenozoic tectono-magmatic and metallogenic processes in the Sanjiang region,southwestern China[J].Earth-Science Reviews,138:268-299.
Deng J, Wang Q F, Li G J,et al,2015.Geology and genesis of the giant Beiya porphyry-skarn gold deposit,northwestern Yangtze Block,China[J].Ore Geology Reviews,70:457-485.
Deng Jinfu, Zhao Hailing, Mo Xuanxue,et al,1996.Root Column Structure and Key to Continental Dynamics in Chinese Mainland[M].Beijing:Geological Publishing House.
Deng Jun, Wang Qingfei, Chen Fuchuan,et al,2020. Superimposed orogeny and composite metallogenic system:Case study from the Sanjiang Tethyan belt,SW China[J].Acta Petrologica Sinica,32(8):2225-2247.
Deng Wanming, Huang Xuan, Zhong Dalai,1998.Alkali rich porphyry in the northern segment of Jinshajiang belt in western Yunnan and its relationship with intraplate deformation[J].Science in China(Series D),28(2):111-117.
Du B, Wang C M, Yang L F,et al,2020.Petrogenesis of the Cenozoic Lianhuashan pluton(SW China):Constrained by zircon U-Pb geochronology,Lu-Hf isotope,and geochemistry[J].Geological Journal,55 (5):3377-3400.
Du Bin,2020.Lithospheric Material Structure of the Sanjiang Tethys Orogenic Belt and Its Constraints on Porphyry Metallogenesis[D].Beijing:China University of Geosciences(Beijing).
Ge Liangsheng,2007.Alkali-rich Magmatism and Au-polymetal Metallogenic System in Northwestern Yunnan[D].Beijing:China University of Geosciences(Beijing).
Ge Liangsheng, Guo Xiaodong, Zou Yilin,et al,2003.Genesis and geochemical characteristics of alkali-rich rock bodies(dykes) in the northwest Yunnan Province[J].Contributions to Geology and Mineral Resources Research,(Supp.1):36-42.
Griffin W L, Begg G C, O’reilly S Y,2013.Continental-root control on the genesis of magmatic ore deposits[J].Nature Geoscience,6(11):905-910.
Guo H, Lai Y, Zhou Y T,et al,2020.The role of magma sources,oxygen fugacity,and fractionation in determining the Jiudingshan porphyry‐skarn Cu-Mo deposit in Western Yunnan,China[J].Geological Journal,55(12):7892-7915.
Guo Xiaodong, Li Jianwen, Xia Rui,2014.Study on forming mechanism of Machangqing alkaline-rich intrusive rock in western Yunnan[J].Geological Review,60(1):125-137.
Guo Z F, Hertogen J, Liu J Q,et al,2005.Potassic Magmatism in Western Sichuan and Yunnan Provinces,SE Tibet,China:Petrological and geochemical constraints on petrogenesis[J].Journal of Petrology,46(1):33-78.
Guo Z F, Wilson M, Zhang M L,2015.Post-collisional ultrapotassic mafic magmatism in South Tibet:Products of partial melting of pyroxenite in the mantle wedge induced by roll-back and delamination of the subducted Indian continental lithosphere slab[J].Journal of Petrology,56(7):1365-1406.
Hart S R,1984.Heterogeneous mantle domains:Signatures,genesis and mixing chronologies[J].Earth and Planetary Science Letters,90(3):273-296.
Hawkesworth C J, Kemp A I S,2006.Using hafnium and oxygen isotopes in zircons to unravel the record of crustal evolution[J].Chemical Geology,226(3/4):144-162.
He W Y, Mo X X, He Z H,et al,2015.The geology and mineralogy of the Beiya skarn gold deposit in Yunnan,Southwest China[J].Economic Geology,110(6):1625-1641.
He W Y, Mo X X, Yang L Q,et al,2016.Origin of the Eocene porphyries and mafic microgranular enclaves from the Beiya porphyry Au polymetallic deposit,western Yunnan,China:Implications for magma mixing/mingling and mineralization[J].Gondwana Research,40:230-248.
He W Y, Yang L Q, Brugger J,et al,2017.Hydrothermal evolution and ore genesis of the Beiya giant Au polymetallic deposit,western Yunnan,China:Evidence from fluid inclusions and H-O-S-Pb isotopes[J].Ore Geology Reviews,90:847-862.
He Wenyan, Mo Xuanxue, Yu Xuehui,et al,2011.Geochronological study of magmatic intrusions and mineralization of Machangqing porphyry Cu-Mo-Au deposit,western Yunnan Province[J].Earth Science Frontiers,18(1):207-215.
He Wenyan, Mo Xuanxue, Yu Xuehui,et al,2014.Genesis and geodynamic settings of lamprophyres from Beiya,western Yunnan:Constraints from geochemistry,geochronology and Sr-Nd-Pb-Hf isotopes[J].Acta Petrologica Sinica,30(11):3287-3300.
Henley-Cohn J, Hausfeld J N,1984.Iontophoretic treatment of oral herpes[J].Laryngoscope,94(1):118-121.
Hoefs J,1997.Stable Isotope Geochemistry (4th Edition)[M].4th ed.Berlin:Springer-Verlag.
Hong Tao, You Jun, Wu Chu,et al,2015.Archean-Paleoproterozoic zircon from a granite porphyry in the Taohua area,western Yunnan and their constrain on the basement of western margin of Yangtze plate[J].Acta Petrologica Sinica,31(9):2583-2596.
Hou Z Q, Wang L Q, Zaw K,et al,2003.Post-collisional crustal extension setting and VHMS mineralization in the Jinshajiang orogenic belt,southwestern China[J].Ore Geology Reviews,22(3/4):177-199.
Hou Z Q, Zhou Y, Wang R,et al,2017.Recycling of metal-fertilized lower continental crust:Origin of non-arc Au-rich porphyry deposits at cratonic edges[J].Geology,45(6):563-566.
Hou Zengqian, Mo Xuanxue, Yang Zhiming,et al,2006.Metallogeneses in the collisional orogen of the Qinghai-Tibet Plateau:Tectonic setting,tempo-spatial distribution and ore deposit types[J].Geology in China,(2):340-351.
Hou Zengqian, Wang Erqi,2008.Metallogenesis of the Indo-Asian Collisional Orogen:New advances[J].Acta Geoscientica Sinica,(2):275-292.
Hou Zengqian, Xu Bo, Zheng Yuanchuan,et al,2021.Mantle flow:The deep mechanism of large-scale growth in Tibetan Plateau[J].Chinese Science Bulletin,66(21):2671-2690.
Hou Zengqian, Zheng Yuanchuan, Lu Zhanwu,et al,2020.Growth,thickening and evolution of the thickened crust of the Tibet Plateau[J].Acta Geologica Sinica,94(10):2797-2815.
Hou Zengqian, Zhong Dalai, Deng Wanming,2004.A tectonic model for porphyry copper-molybdenum-gold metallogenic belts on the eastern margin of the Qinghai-Tibet Plateau[J].Geology in China,31(1):1-14.
Hu Xiangzhao, Huang Zhen,1997.The petrology and petrogenesis of the Yangtze platform western margin’s alkali-rich granite porphyty[J].Geotectonica et Metallogenia,21(2):173-180.
Huang Jiqing, Chen Guoming, Chen Bingwei,1984.Analysis of Tethys-Himalayan tectonic domain[J].Acta Geologoca Sinica,(1):1-17.
Huang X L, Niu Y L, Xu Y G,et al,2010.Mineralogical and Geochemical Constraints on the Petrogenesis of Post-collisional Potassic and Ultrapotassic Rocks from Western Yunnan,SW China[J].Journal of Petrology,51(8):1617-1654.
Huang Xiaolong, Xu Yigang, Yang Qijun,et al,2007.Geochemistry of late Eocene high-Mg ultrapotassic from western Yunnan,China:Constraints on Petrogenesis[J].Geochimica,(2):120-138.
Huang Yonggao, Luo Gai, Zhang Tong,et al,2018.Characteristics of Chronology and Geochemistry for the Cenozoic alkali-rich porphyry in Lijiang area,western Yunnan and their significance[J].Geoscience,32(1):28-44.
Huang Yupeng,2017.The Petrogenetic Mechanism and Metallogenetic Potentiality of Bengge Alkaline Igneous Complex,Northwest Yunnan[D].Chengdu:Chengdu University of Technology.
Jahn B M, Wu F Y, Capdevila R,2001.Highly evolved juvenile granites with tetrad REE patterns:the Woduhe and Baerzhe granites from the Great Xing’an Mountains in NE China[J].Lithos,59(4):171-198.
Jia Liqiong, Mo Xuanxue, Dong Guochen,et al,2013.Genesis of lamprophyres from Machangqing,western Yunnan:Constraints from geochemistry,geochronology and Sr-Nd-Pb-Hf isotopes[J].Acta Petrologica Sinica,29(4):1247-1260.
Jia Ruya, Liao Shiyong, Liu Zheng,et al,2016.Petrogenesis and tectonic implications of the Eocene Weishan pluton from western Yunnan[J].Geology in China,43(1):132-141.
Kelley K A, Cottrell E,2009.Water and the oxidation state of subduction zone magmas[J].Science,325(5940):605-607.
Kelly J, Rothstein J, Grossman S P,1979.GABA and hypothalamic feeding systems. I. Topographic analysis of the effects of microinjections of muscimol[J].Physiology and Behavior,23,(6):1123-1134.
Kou Caihua, Zhang Zhaochong, Hou Tong,et al,2011.OIB-type picritic porphyrite from Jianchuan in the western Yunnan Province:Results of break-off of the sunducting plate?[J].Acta Petrologica Sinica,27(9):2679-2693.
Lai S C, Liu C Y, O’Reilly S Y,2001.Petrogenesis and its significance to continental dynamics of the Neogene high-potassium calc-alkaline volcanic rock association from north Qiangtang,Tibetan Plateau[J].Science in China Series D:Earth Sciences,44:45-55.
Le Maitre R W,2002.Igneous Rocks:A Classification and Glossary of Terms[M].Cambridge:Cambridge University Press.
Li W C, Wang J H, He Z H,et al,2016.Formation of Au-polymetallic ore deposits in alkaline porphyries at Beiya,Yunnan,Southwest China[J].Ore Geology Reviews,73:241-252.
Li W K, Yang Z M, Chiaradia M,et al,2021.Enrichment nature of ultrapotassic rocks in southern Tibet inherited from their mantle source[J].Journal of Petrology,62(8):egab060.
Li X H, Zhou H W, Chung S L,et al,2002.Geochemical and Sr-Nd isotopic characteristics of late Paleogene ultrapotassic magmatism in southeastern Tibet[J]. International Geology Review,44(6):559-574.
Li X Z, Yin C Q, Gao P,et al,2022.Petrogenesis and tectonic implications of Eocene-Oligocene potassic felsic porphyries in the Sanjiang region,southeastern Tibetan Plateau[J].Journal of Asian Earth Sciences,232:105209.
Li Xianhua, Zhou Hanwen, Wei Gangjian,et al,2002.Geochemistry and Sr-Nd isotopes of Cenozoic ultrapotassic lamprophyres in western Yunnan:Constraints on the composition of sub-continental lithospheric mantle[J].Geochimica,31(1):26-34.
Li Yong,2012.Geochronology,Petrogenesis and Geological Significance of the Cenozoic Potassic Magmatic Rocks in Sanjiang Area,Western Yunnan[D].Beijing:China University of Geosciences(Beijing).
Li Yong, Mo Xuanxue, Yu Xuehui,et al,2011.Zircon U-Pb dating of several selected alkali-rich porphyries from the Jinshajiang-Ailaoshan fault zone and geological significance[J].Geoscience,25(2):189-200.
Liang H Y, Campbell I H, Allen C M,et al,2007.The age of the potassic alkaline igneous rocks along the Ailaoshan-Red River shear zone:Implications for the onset age of left-lateral shearing[J].The Journal of Geology,115(2):231-242.
Liang Huaying, Xie Yingwen, Zhang Yuquan,et al,2004.Constraints of the formation and evolution of potassium alkaline-rich rocks on copper mineralization:A case study of Machangqing deposit[J].Advances of Natural Science,14(1):118-122.
Liu B, Liu H, Zhang C Q,et al,2015.Geochemistry and geochronology of porphyries from the Beiya gold-polymetallic orefield,western Yunnan,China[J].Ore Geology Reviews,69:360-379.
Liu Xianfan, Liu Jiaduo, Zhang Chengjiang,2004.Isotopic geochemistry of rock mass and ore-vein from alkaline-rich porphyry type deposits in western Yunnan,China[J].Bulletin of Mineralogy,Petrology and Geochemistry,23(1):32-39.
Liu Xianfan, Zhan Xinzhi, Gao Zhenmin,et al,1999.Deep xenoliths in alkalic porphyry,Liuhe,Yunnan,and implications to petrogenesis of alkalic porphyry and associated mineralizations[J].Science in China(Series D),30(5):413-420.
Liu Z, Liao S Y, Wang J R,et al,2017.Petrogenesis of late Eocene high Ba-Sr potassic rocks from western Yangtze Block,SE Tibet:A magmatic response to the Indo-Asian collision[J].Journal of Asian Earth Sciences,135:95-109.
Liu Z, Liao S Y, Zhou Q,et al,2018.Petrogenesis of ore-bearing porphyry in non-subduction setting:A case study of the Eocene potassic intrusions in the western Yangtze Block[J].Mineralogy and Petrology,112(6):801-817.
Boxi Lü, Qian Xianggui,1999.Petrology of deep xenoliths of Cenozoic alkaline volcanic rocks and alkali rich porphyry in western Yunnan[J].Yunnan Geology,18(2):127-143.
Boxi Lü, Qian Xianggui,2000.The Tectonic type of cenozoic alkaline magmatic rock series in Three-River area,West Yunnan[J].Yunnan Geology,(3):232-243.
Lu Y J, Campbell M T, Li Z X,et al,2015.Paleogene post-collisional lamprophyres in western Yunnan,western Yangtze Craton:Mantle source and tectonic implications[J].Lithos,233:139-161.
Lu Y J, Kerrich R, Campbell M T,et al,2013a.Geochemical,Sr-Nd-Pb,and zircon Hf-O isotopic compositions of eocene-oligocene Shoshonitic and Potassic Adakite-like Felsic intrusions in western Yunnan,SW China:Petrogenesis and tectonic implications[J].Journal of Petrology,54(7):1309-1348.
Lu Y J, Kerrich R, Cawood P A,et al,2012.Zircon SHRIMP U-Pb geochronology of potassic felsic intrusions in western Yunnan,SW China:Constraints on the relationship of magmatism to the Jinsha suture[J].Gondwana Research,22(2):737-747.
Lu Y J, Kerrich R, Mccuaig T C,et al,2013b.Intracontinental Eocene-Oligocene porphyry Cu mineral systems of Yunnan,Western Yangtze Craton,China:Compositional characteristics,sources,and implications for continental collision metallogeny[J].Economic Geology,108:1541-1576.
Lu Y J, Loucks R R, Fiorentini M,et al,2016.Zircon compositions as a pathfinder for porphyry Cu ± Mo ± Au deposits[J].Society of Economic Geologists Special Publications Series,19:329-347.
Mo Xuanxue, Zhao Zhidan, Yu Xuehui,2009.Collision and Post-collision Cenozoic Igneous Rocks in Tibet Plateau[M].Beijing:Geological Publishing House.
Müller D, Rock N M S, Groves D I,1992.Geochemical discrimination between shoshonitic and potassic volcanic rocks in different tectonic settings:A pilot study[J].Mineralogy and Petrology,46(4):259-289.
Nelson D R,1992.Isotopic characteristics of potassic rocks:evidence for the involvement of subducted sediments in magma genesis[J].Lithos,28(3/4/5/6):403-420.
Peacock S M, Rushmer T, Thompson A B,1994.Partial melting of subducting oceanic crust[J].Earth and Planetary Science Letters,121(1/2):227-244.
Quan Haihui, Chai Peng, Yuan Lingling,2023.Exploration of the origin and geological significance of potassium magmatic rocks from eocene to oligocene in Western Yunnan[C]//Collected Papers of the 2nd National Mineral Exploration Conference.Weihai:China Geophysical Association: 555-557.
Rickwood P C,1989.Boundary lines within petrologic diagrams which use oxides of major and minor elements[J].Lithos,22(4):247-263.
Seal R R,2006.Sulfur isotope geochemistry of sulfide minerals[J].Reviews in Mineralogy and Geochemistry,61(1):633-677.
Sun C D, Wu P, Wang D,et al,2017.Geochemistry and zircon U-Pb age of the Yao’an pseudoleucite porphyry,Yunnan Province,China[J].Acta Geochimica,36 (2):316-328.
Wang C M, Bagas L, Lu Y J,et al,2016.Terrane boundary and spatio-temporal distribution of ore deposits in the Sanjiang Tethyan Orogen:Insights from zircon Hf-isotopic mapping[J].Earth-Science Reviews,156:39-65.
Wang Denghong, Qu Wenjun, Li Zhiwei,et al,2004.The metallogenic concentrated epoch of the porphyry copper (molybdenum) deposits in Jinshajiang-Honghe metallogenic belt:Re-Os isotope dating[J].Science in China (Series D),(4):345-349.
Wang Dongbing, Tang Yuan, Luo Liang,et al,2017.Late Oligocene crustal anatexis and melt/fluid migration in the Ailaoshan tectonic belt:Evidences from zircon U-Pb ages and trace element compositions[J].Acta Petrologica Sinica,33(7):2037-2053.
Wang Hong, Zhang Jinrang, Zhou Qing,et al,2019.Zircon U-Pb age and geochemistry of the Guangmashan monzonitic porphyry in Ninglang,Yunnan Province[J].Geological Bulletin of China,38(11):1858-1866.
Wang J H, Yin A, Harrison T M,et al,2001.A tectonic model for Cenozoic igneous activities in the eastern Indo-Asian collision zone[J].Earth And Planetary Science Letters,188(1):123-133.
Wang Jian, Li Jianping, Wang Jianghai,2003.Shoshonitic magmatism in Dali-Jianchuan area,western Yunnan:A geochemical study of arc magmatism in a post-collisional strike-slip extensional setting[J].Acta Petrologica Sinica,19(1):61-70.
Wang Jianhua, Li Wenchang, He Zhonghua,et al,2016.Geological and Sr-Nd-Pb isotopic characteristics of the Dashadi porphyry in the Beiya gold polymetallic deposit in western Yunnan and their geological implications[J].Acta Petrologica Sinica,32(8):2367-2378.
Wang Tao, Zhang Jing, Tong Zida,et al,2018.LA-ICP-MS zircon U-Pb geochronology and geochemistry characteristics of the Lianhuashan alkaline-rich porphyry intrusion in western Yunnan Province[J].Geoscience,32(3):438-452.
Wang W, Zeng L S, Gao L E,et al,2018.Eocene-Oligocene potassic high Ba-Sr granitoids in the Southeastern Tibet:Petrogenesis and tectonic implications[J].Lithos,322:38-51.
Wang Y J, Wang X S, Bi X W,et al,2020.Intraplate adakite-like rocks formed by differentiation of mantle-derived mafic magmas:A case study of Eocene intermediate-felsic porphyries in the Machangqing porphyry Cu-Au mining district,SE Tibetan Plateau[J].Journal of Asian Earth Sciences,196:104364.
Wang Y, Foley S F, Buhre S,et al,2021.Origin of potassic postcollisional volcanic rocks in young,shallow,blueschist-rich lithosphere[J].Science Advances,7(29):eabc0291.
Wang Zhihua, Guo Xiaodong, Chen Xiang,et al,2010.Geochemistry characteristics of Machangqing Alkaline-rich intrusives,Yunnan,and its forming tectonic settings[J].Geological Review,56(1):125-135.
Wilkinson J J,2013.Triggers for the formation of porphyry ore deposits in magmatic arcs[J].Nature Geoscience,6(11):917-925.
Wu Jingkai, Zhao Zhidan, Yang Yiyun,et al,2019.Petrogenesis and geological implications of the alkali-rich porphyry in southern Ailaoshan-Red River shear zone[J].Acta Petrologica Sinica,5(2):485-504.
Wu Kaixing,2005.The Cenozoic Alkali-rich Igneous Rocks Western Yunnan and Their Relation with Metallogenesis of Gold-Exemplified by the Beiya Gold Deposit[D].Guangzhou:Graduate School of the Chinese Academy of Sciences(Institute of Geochemistry).
Wyllie P J,1977.Crustal anatexis:An experimental review[J].Tectonophysics,43(1/2):41-71.
Xia Bin, Lin Qingcha, Zhang Yuquan,2005.Zircon SHRIMP dating of diopside granite in Ailaoshan-Jinshajiang rock belt and its geological implications-example for Yuzhaokuai,Matouwan and Shilicun diopside granites[J].Geotectonica et Metalogenia,29(1):35-43.
Xia Bin, Lin Qingcha, Zhang Yuquan,2006.Qinghai-Tibet Plateau and its genesis and geological implications[J].Acta Geologica Sinica,80(8):1189-1196.
Xia L Q, Li X M, Ma Z P,et al,2011.Cenozoic volcanism and tectonic evolution of the Tibetan Plateau[J].Gondwana Research,19(4):850-866.
Xia P, Xu Y G,2005.Domains and enrichment mechanism of the lithospheric mantle in western Yunnan:A comparative study on two types of Cenozoic ultrapotassic rocks[J].Science in China(Series D),48(3):326-337.
Xia Ping, Xu Yigang,2004.Zoning and enrichment mechanism of the lithospheric mantle inwestern Yunnan Province:Acomparative study about two types of the Cenozoic ultra-potassic rocks[J].Science in China (Series D),34(12):1118-1128.
Xin T, Zhao Z D, Niu Y L,et al,2019.Petrogenesis and tectonic implications of the Eocene-Oligocene potassic felsic suites in western Yunnan,eastern Tibetan Plateau:Evidence from petrology,zircon chronology,elemental and Sr-Nd-Pb-Hf isotopic geochemistry[J].Lithos,340/341:287-315.
Xing Junbing, Guo Xiaodong, Qu Wenjun,et al,2009.Molybdenite Re-Os Age and other geological meaning of Machangqing porphyry copper molybdenum deposit[J].Gold Science and Technology,17(5):24-29.
Xu B, Hou Z Q, Griffin W L,et al,2021.Cenozoic lithospheric architecture and metallogenesis in southeastern Tibet[J].Earth-Science Reviews,214:103472.
Xu Heng, Cui Yinliang, Zhou Jiaxi,et al,2015.Petrogenesis and dynamic background of porphyry in Bijiashan Cu depisit,Yunnan Province,China:Geochemistry and geochronology constraints[J].Acta Mineralogica Sinica,35(4):439-446.
Xu Heng, Cui Yinliang, Zhou Jiaxi,et al,2016.Geochemistry and zircon U-Pb age of the alkali-rich porphyry in the Fenshuiling ore district,Yongsheng City,Yunnan Province,and its geological implications[J].Geotectonica et Metallogenia,40(3):614-624.
Xu L L, Bi X W, Hu R Z,et al,2016.Redox states and genesis of magmas associated with intra-continental porphyry Cu-Au mineralization within the Jinshajiang-Red River alkaline igneous belt,SW China[J].Ore Geology Reviews,73:330-345.
Xu L L, Zhu J J, Huang L M,et al,2023.Genesis of hydrous-oxidized parental magmas for porphyry Cu (Mo,Au) deposits in a postcollisional setting:Examples from the Sanjiang region,SW China[J].Miner Deposita,58:161-196.
Xu Y G, Menzies M A, Thirlwall M F,et al,2001.Exotic lithosphere mantle beneath the western Yangtze Craton:Petrogenetic links to Tibet using highly magnesian ultrapotassic rocks[J].Geology,29(9):863-866.
Xu Zhiqin, Wang Qin, Li Zhonghai,2016.Indo-Asian collision:Tectonic transition from compression to strike slip[J].Acta Geologoca Sinica,90(1):1-23.
Xue Chunji, Chen Yuchuan, Yang Jianmin,et al,2002.Analysis of ore forming background and tectonic system of Lanping Basin,western Yunnan Province[J].Mineral Deposits,(1):36-44 .
Yan Q G, Jiang X J, Li C,et al,2018.Geodynamic background of intracontinental Cenozoic Alkaline volcanic rocks in Laojiezi,Western Yangtze Craton:Constraints from Sr‐Nd‐Hf‐O isotopes[J].Acta Geologica Sinica-English Edition,92(6):2098-2119.
Yang M M, Zhao F F, Liu X F,et al,2020.Contribution of magma mixing to the formation of porphyry-skarn mineralization in a post-collisional setting:The Machangqing Cu-Mo-(Au) deposit,Sanjiang tectonic belt,SW China[J].Ore Geology Reviews,122:103518.
Yang T N, Liang M J, Fan J W,et al,2014.Paleogene sedimentation,volcanism,and deformation in eastern Tibet:Evidence from structures,geochemistry,and zircon U-Pb dating in the Jianchuan Basin,SW China[J].Gondwana Research,26(2):521-535.
Yang Yufan,2017.The Study for Glass Inclusions from Quarte Enclave in Alkaline-rich Porphyry in Western Yunnan,China[D].Chengdu:Chengdu University of Technology.
Yang Z M, Goldfarb R, Chang Z S,2016.Generation of postcollisional porphyry copper deposits in southern Tibet triggered by subduction of the Indian continental plate[J].SEG Special Publication,19:279-300.
Yu Li, Li Gongjian, Wang Qingfei,et al,2014.Petrogenesis and tectonic significance of the Late Cretaceous magmatism in the northern part of the Baoshan block:Constraints from bulk geochemistry,zircon U-Pb geochronology and Hf isotopic compositions[J].Acta Petrologica Sinica,(9):2709-2724.
Zajacz Z, Halter W,2009.Copper transport by high temperature,sulfur-rich magmatic vapor:Evidence from silicate melt and vapor inclusions in a basaltic andesite from the Villarrica volcano (Chile)[J].Earth and Planetary Science Letters,282(1):115-121.
Zeng Pusheng, Hou Zengqian, Gao Yongfeng,et al,2006.The Himalayan Cu-Mo-Au mineralization in the eastern Indo-Asian collision zone:Constraints from Re-Os dating ofmolybdenite[J].Geological Review,(1):72-84.
Zhang Guangning, Deng Jun, Ye Jinhua,2015.Magma mixing in the Machangjing copper-bearing alkali-rich porphyry of western Yunnan:Evidence of petrology and geochemistry[J].Geology and Exploration,51(4):599-609.
Zhang L S, Schaerer U,1999.Age and origin of magmatism along the Cenozoic Red River shear belt,China[J].Contributions to Mineralogy and Petrology,134(1):67-85.
Zhang Xiang, Yu Wenxiu, Liu Lichao,2016.Geochemical characteristics and genesis of alkali-rich porphyry in Xiaolongtan mining area of western Yunnan[J].Mineral Resources and Geology,30(4):561-597.
Zhang Yong,2017.Geochronology and Geochemistry of Alkali-rich Porphyries and Its Xenoliths in Liuhe and Xiaoqiaotou,Western Yunnan[D].Beijing:China University of Geosciences(Beijing).
Zhang Yuquan, Xie Yingwen,1995.Geochemistry of Granite in Hengduan Mountain Area[M].Beijing:Science Press.
Zhao Fufeng,2012.Evolution of Cenozoic Alkaline-rich Magma and Mantle Fluid from Western Yunnan Province and the Related Metallogenic Effect[D].Chengdu:Chengdu University of Technology.
Zhao Xin, Yu Xuehui, Mo Xuanxue,et al,2004.Petrological and geochemical of Cenozoic alkali-rich porphyries and xenoliths in western Yunnan Province[J].Geoscience,18(2):217-228.
Zhao Yuanxin,2017.The Geochronology,Geochemisty of the Jiudingshan and Baofengsi Porphyry in Dali Yunnan[D].Beijing:China University of Geosciences(Beijing).
Zhao Z D, Mo X X, Dilek Y,et al,2009.Geochemical and Sr-Nd-Pb-O isotopic compositions of the post-collisional ultrapotassic magmatism in SW Tibet:Petrogenesis and implications for India intra-continental subduction beneath southern Tibet[J].Lithos,113(1/2):190-212.
Zhou J, Li S Z, Wang G H,et al,2018.Petrogenesis of Eocene mineralized porphyry in Bijiashan,eastern margin of Tibet Plateau:Constraints from geochronology,geochemistry and Hf isotopes[J].Lithos,316/317:1-18.
Zhou Jie, Wang Genhou, Zhang Li,2017.Petrogenesis and geological significance of the Eocene porphyry in the Xiaolongtan mining area of the western Yunnan,China[J].Journal of Chengdu University of Technology (Science and Technology Edition),44(3):334-349.
Zhou Ting, Bi Xianwu, Wang Die,et al,2013.Lithium isotopic characteristics of ore-bearing and barren intrusions in the Jinshajiang-Honghe alkali-rich intrusive belt[J].Acta Mieralogica Sinica,33(2):221-230.
Zhou Y, Hou Z Q, Wang R,et al,2023.Origin of biotite-rich xenoliths in the Eocene Beiya porphyry:Implications for upper-crustal Au remobilization and formation of giant porphyry Au systems in a collisional setting[J]. Lithos,442:107063.
Zhou Y, Xu B, Wang R,et al,2019.Petrogenesis of Cenozoic high-Sr/Y shoshonites and associated mafic microgranular enclaves in an intracontinental setting:Implications for porphyry Cu-Au mineralization in western Yunnan,China[J].Lithos,324/325:39-54.
Zhu Bingquan, Zhang Yuquan, Xie Yingwen,1992.Nd,Sr and Pb isotopic characteristics of Cenzoic ultra-potassic volcanic rocks from eastern for subcontinent-mantle evolution in southwestern China[J].Geochimica,(3):201-212.
Zindler A, Hart S R,1986.Chemical Geodynamics[J].Annual Review of Earth & Planetary Sciences,14(1):493-571.
鲍新尚,和文言,高雪,2017.滇西北衙金矿床富水岩浆对成矿的制约[J].岩石学报,33(7):2175-2188.
毕献武,胡瑞忠, Cornell D H,2001.富碱侵入岩与金成矿关系:云南省姚安金矿床成矿流体形成演化的微量元素和同位素证据[J].地球化学,30(3):264-272.
毕献武,胡瑞忠,彭建堂,等,2005.姚安和马厂箐富碱侵入岩体的地球化学特征[J].岩石学报,21(1):115-126.
毕献武,胡瑞忠,叶造军,等,1999.A型花岗岩类与铜成矿关系研究——以马厂箐铜矿为例[J].中国科学(D辑:地球科学),29(6):489-495.
蔡新平,1992.扬子地台西缘新生代富碱斑岩中的深源包体及其意义[J].地质科学,(2):183-189.
楚亚婷,2016.深部地质过程中流体作用及流体演化研究[D].成都:成都理工大学.
邓晋福,赵海玲,莫宣学,等,1996.中国大陆根—柱构造—大陆动力学的钥匙[M].北京:地质出版社.
邓军,王庆飞,李龚健,2016.复合造山和复合成矿系统:三江特提斯例析[J].岩石学报,32(8):2225-2247.
邓万明,黄萱,钟大赉,1998.滇西金沙江带北段的富碱斑岩及其与板内变形的关系[J].中国科学(D辑:地球科学),28(2):111-117.
杜斌,2020.三江特提斯造山带岩石圈物质结构及其对斑岩成矿约束[D].北京:中国地质大学(北京).
葛良胜,2007.滇西北富碱岩浆活动与金多金属成矿系统[D].北京:中国地质大学(北京).
葛良胜,郭晓东,邹依林,等,2003.滇西北地区富碱岩体(脉)地球化学特征及成因[J].地质找矿论丛,(增1):36-42.
郭晓东,李建文,夏锐,等,2014.滇西马厂箐富碱侵入岩体形成机制研究[J].地质论评,60(1):125-137.
和文言,莫宣学,喻学惠,等,2011.滇西马厂箐斑岩型铜钼(金)矿床成岩成矿时代研究[J].地学前缘,18(1):207-215.
和文言,莫宣学,喻学惠,等,2014.滇西北衙煌斑岩的岩石成因及动力学背景:年代学、地球化学及Sr-Nd-Pb-Hf同位素约束[J].岩石学报,30(11):3287-3300.
洪涛,游军,吴楚,等,2015.滇西桃花花岗斑岩中新太古代—古元古代锆石年龄信息:对扬子板块西缘基底时代的约束[J].岩石学报,31(9):2583-2596.
侯增谦,莫宣学,杨志明,等,2006.青藏高原碰撞造山带成矿作用:构造背景、时空分布和主要类型[J].中国地质,(2):340-351.
侯增谦,王二七,2008.印度—亚洲大陆碰撞成矿作用主要研究进展[J].地球学报,(3):275-292.
侯增谦,许博,郑远川,等,2021.地幔通道流:青藏高原大规模生长的深部机制[J].科学通报,66(21):2671-2690.
侯增谦,郑远川,卢占武,等,2020.青藏高原巨厚地壳:生长、加厚与演化[J].地质学报,94(10):2797-2815.
侯增谦,钟大赉,邓万明,2004.青藏高原东缘斑岩铜钼金成矿带的构造模式[J].中国地质,31(1):1-14.
胡祥昭,黄震,1997.扬子地台西缘富碱花岗斑岩特征及成因探讨[J].大地构造与成矿学,21(2):173-180.
黄汲清,陈国铭,陈炳蔚,1984.特提斯—喜马拉雅构造域初步分析[J].地质学报,(1):1-17.
黄小龙,徐义刚,杨启军,等,2007.滇西晚始新世高镁富钾火山岩的地球化学特征及其岩石成因机制探讨[J].地球化学,(2):120-138.
黄永高,罗改,张彤,等,2018.滇西丽江地区新生代富碱斑岩年代学、地球化学特征及其地质意义[J].现代地质,32(1):28-44.
黄玉蓬,2017.滇西北甭哥碱性杂岩体成岩机制研究与成矿潜力分析[D].成都:成都理工大学.
贾丽琼,莫宣学,董国臣,等,2013.滇西马厂箐煌斑岩成因:地球化学、年代学及Sr-Nd-Pb-Hf同位素约束[J].岩石学报,29(4):1247-1260.
贾儒雅,廖世勇,刘铮,等,2016.滇西始新世巍山岩体的岩石学成因及构造意义[J].中国地质,43(1):132-141.
寇彩化,张招崇,侯通,等,2011.滇西剑川OIB型苦橄玢岩:俯冲板块断离的产物?[J].岩石学报,27(9):2679-2693.
李献华,周汉文,韦刚健,等,2002.滇西新生代超钾质煌斑岩的元素和Sr-Nd同位素特征及其对岩石圈地幔组成的制约[J].地球化学,31(1):26-34.
李勇,2012.滇西“三江”地区新生代钾质岩浆岩年代学特征、岩石成因及其地质意义[D].北京:中国地质大学(北京).
李勇,莫宣学,喻学惠,等,2011.金沙江—哀牢山断裂带几个富碱斑岩体的锆石U-Pb定年及地质意义[J].现代地质,25(2):189-200.
梁华英,谢应雯,张玉泉,等,2004.富钾碱性岩体形成演化对铜矿成矿制约——以马厂箐铜矿为例[J].自然科学进展,14(1):118-122.
刘显凡,刘家铎,张成江,等,2004.滇西富碱斑岩型矿床岩体和矿脉同位素地球化学研究[J].矿物岩石地球化学通报,23(1):32-39.
刘显凡,战新志,高振敏,等,1999.云南六合深源包体与富碱斑岩成岩成矿的关系[J].中国科学(D辑:地球科学),30(5):413-420.
吕伯西,钱祥贵,1999.滇西新生代碱性火山岩、富碱斑岩深源包体岩石学研究[J].云南地质,18(2):127-143.
吕伯西,钱祥贵,2000.滇西三江地区新生代碱性系列岩浆岩构造类型[J].云南地质,(3):232-243.
莫宣学,赵志丹,喻学惠,2009.青藏高原新生代碰撞—后碰撞火成岩[M].北京:地质出版社.
全海辉,柴鹏,袁玲玲,2023.滇西始新世—渐新世钾质岩浆岩成因及其地质意义探讨[C]//第二届全国矿产勘查大会论文集.威海:中国地球物理协会: 555-557.
王登红,屈文俊,李志伟,等,2004.金沙江—红河成矿带斑岩铜钼矿的成矿集中期:Re-Os同位素定年[J].中国科学(D辑:地球科学),(4):345-349.
王冬兵,唐渊,罗亮,等,2017.哀牢山构造带晚渐新世地壳深熔与熔/流体迁移:锆石U-Pb年龄与微量元素证据[J].岩石学报,33(7):2037-2053.
王宏,张锦让,周清,等,2019.云南宁蒗光马山二长斑岩岩石地球化学及锆石U-Pb年龄[J].地质通报,38(11):1858-1866.
王建,李建平,王江海,2003.滇西大理—剑川地区钾玄质岩浆作用:后碰撞走滑拉伸环境岛弧型岩浆作用的地球化学研究[J].岩石学报,19(1):61-70.
王建华,李文昌,和中华,等,2016.滇西北衙金矿区大沙地岩体地质特征、Sr-Nd-Pb同位素及地质意义[J].岩石学报,32(8):2367-2378.
王涛,张静,佟子达,等,2018.滇西莲花山富碱斑岩体LA-ICP-MS锆石U-Pb年代学、地球化学特征及其地质意义[J].现代地质,32(3):438-452.
王治华,郭晓东,陈祥,等,2010.云南祥云马厂箐富碱斑岩体的地球化学特征及其形成的构造环境[J].地质论评,56(1):125-135.
吴开兴,2005.滇西新生代富碱火成岩及其与金成矿关系研究[D].广州:中国科学院研究生院(地球化学研究所).
武精凯,赵志丹,杨逸云,等,2019.云南哀牢山—红河断裂带南段新生代富碱斑岩岩石成因和地质意义[J].岩石学报,5(2):485-504.
夏斌,林清茶,张玉泉,2005.哀牢山—金沙江岩带透辉石花岗岩锆石SHRIMPU-Pb年龄及地质意义——以玉召块、马头湾和十里村岩体为例[J].大地构造与成矿学,29(1):35-43.
夏斌,林清茶,张玉泉,2006.青藏高原东部新生代钾质碱性系列岩石地球化学特征:岩石成因及其地质意义[J].地质学报,80(8):1189-1196.
夏萍,徐义刚,2004.滇西岩石圈地幔域分区和富集机制:新生代两类超钾质火山岩的对比研究[J].中国科学(D辑:地球科学),34(12):1118-1128.
邢俊兵,郭晓东,屈文俊,等,2009.马厂箐斑岩型铜、钼矿辉钼矿Re-Os年龄及地质意义[J].黄金科学技术,17(5):24-29.
徐恒,崔银亮,周家喜,等,2015.云南大理笔架山铜矿区斑岩成因与动力学背景:年代学和地球化学制约[J].矿物学报,35(4):439-446.
徐恒,崔银亮,周家喜,等,2016.云南永胜分水岭矿区富碱斑岩地球化学、锆石U-Pb年龄及其地质意义[J].大地构造与成矿学,40(3):614-624.
许志琴,王勤,李忠海,等,2016.印度—亚洲碰撞:从挤压到走滑的构造转换[J].地质学报,90(1):1-23.
薛春纪,陈毓川,杨建民,等,2002.滇西兰坪盆地构造体制和成矿背景分析[J].矿床地质,(1):36-44.
杨雨凡,2017.滇西富碱斑岩石英包体中玻璃包裹体研究[D].成都:成都理工大学.
禹丽,李龚健,王庆飞,等,2014.保山地块北部晚白垩世岩浆岩成因及其构造指示:全岩地球化学,锆石U-Pb年代学和 Hf 同位素制约[J].岩石学报,(9):2709-2724.
曾普胜,侯增谦,高永峰,等,2006.印度—亚洲碰撞带东段喜马拉雅期铜—钼—金矿床Re-Os年龄及成矿作用[J].地质论评,(1):72-84.
张广宁,邓军,叶锦华,等,2015.滇西马厂箐复式岩体岩浆混合作用:岩石学与地球化学证据[J].地质与勘探,51(4):599-609.
张翔,于文修,刘利超,2016.滇西小龙潭矿区富碱斑岩地球化学特征与成因[J].矿产与地质,30(4):561-597.
张泳,2017.滇西六合与小桥头富碱斑岩及其深源包体的年代学和地球化学[D].北京:中国地质大学.
张玉泉,谢应雯,1995.横断山区花岗岩类地球化学[M].北京:科学出版社.
赵甫峰,2012.滇西新生代富碱岩浆与地幔流体演化及其成矿效应研究[D].成都:成都理工大学.
赵欣,喻学惠,莫宣学,等,2004.滇西新生代富碱斑岩及其深源包体的岩石学和地球化学特征[J].现代地质,18(2):217-228.
赵元鑫,2017.云南大理地区九顶山和宝丰寺富碱斑岩的年代学与地球化学[D].北京:中国地质大学(北京).
周洁,王根厚,张莉,2017.滇西小龙潭矿区始新世岩浆岩的成因及其地质意义[J].成都理工大学学报(自然科学版),44(3):334-349.
周汀,毕献武,王蝶,等,2013.金沙江—红河富碱侵入岩带含矿与不含矿富碱斑岩Li同位素地球化学特征及其地质意义[J].矿物学报,33(2):221-230.
朱炳泉,张玉泉,谢应雯,1992.滇西洱海东第三纪超K质火成岩系的Nd-Sr-Pb同位素特征与西南大陆地幔演化[J].地球化学,(3):201-212.
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