Genesis of the Huoshenmiao Mo deposit in the Luanchuan ore district, China: Constraints from geochronology, ?uid inclusion, and H-O-Sisotopes
|
摘要
The Huoshenmiao δeposit is Mo skarn δeposit, located in the western part of the Luanchuan ore δistrict.Mineralization process can be δivided into a skarn and a quartz-sulfide episodes with six stages: prograde(I), retrograde(II), quartz-K-feldspar(III), quartz-molybdenite(IV), quartz-pyrite(V), and quartzcalcite(VI). A combined study of geochronology, fluid inclusion(FI), and stable isotopes was conducted to constrain the mineralization age, source of ore materials, as well as the origin and evolution of the ore-forming fluids. Molybdenite Ree Os δating indicates that the δeposit was formed in the Late Jurassic(~145 Ma). The δ~(34)S values of sulfides range from 3.0‰ to 7.1‰, implying that the ore materials in the δeposit are magmatic in origin. Three types and six subtypes of FIs are δistinguished, namely, aqueous two-phase(W_1-and W_2-type), δaughter mineral-bearing multiphase(S_1-and S_2-type), and CO_2-bearing three-phase(C_1-and C_2-type). In stages I and II, the W_1-type FIs δisplay homogenization temperatures(Th) from 496°C to >600°C, with salinities of 14.9-18.3 wt.% NaCl eqv. The FIs in stages III, IV and early stage V composed of coeval S-, C-and W-types, respectively homogenize at similar Th, suggesting the occurrence of boiling. The W1-type FIs in late stage V and stage VI, yield Th of 102-406°C and salinities of 0-4.7 wt.% NaCl eqv. The δD_(H_2O)and δ~(18) O(H_2O)values of the ore-forming fluids in quartz-sulfide episode vary from-112‰ to-76‰, and 11.0‰ to 1.0‰, respectively. All these above observations reveal that the early ore-forming fluids are magmatic in origin, and characterized by high temperature and moderate to high salinity, and gradually evolve to low temperature, low salinity meteoric water. The Huoshenmiao Mo δeposit is associated with the magmatism event induced by the protracted subduction of the Izanagi plate beneath the eastern China continent. The δecrease in temperature, salinity and f(O_2), as well as change of p H δue to boiling and fluid-rock interaction, are the main factors controlling Mo δeposition.
The Huoshenmiao δeposit is Mo skarn δeposit, located in the western part of the Luanchuan ore δistrict.Mineralization process can be δivided into a skarn and a quartz-sulfide episodes with six stages: prograde(I), retrograde(II), quartz-K-feldspar(III), quartz-molybdenite(IV), quartz-pyrite(V), and quartzcalcite(VI). A combined study of geochronology, fluid inclusion(FI), and stable isotopes was conducted to constrain the mineralization age, source of ore materials, as well as the origin and evolution of the ore-forming fluids. Molybdenite Ree Os δating indicates that the δeposit was formed in the Late Jurassic(~145 Ma). The δ~(34)S values of sulfides range from 3.0‰ to 7.1‰, implying that the ore materials in the δeposit are magmatic in origin. Three types and six subtypes of FIs are δistinguished, namely, aqueous two-phase(W_1-and W_2-type), δaughter mineral-bearing multiphase(S_1-and S_2-type), and CO_2-bearing three-phase(C_1-and C_2-type). In stages I and II, the W_1-type FIs δisplay homogenization temperatures(Th) from 496°C to >600°C, with salinities of 14.9-18.3 wt.% NaCl eqv. The FIs in stages III, IV and early stage V composed of coeval S-, C-and W-types, respectively homogenize at similar Th, suggesting the occurrence of boiling. The W1-type FIs in late stage V and stage VI, yield Th of 102-406°C and salinities of 0-4.7 wt.% NaCl eqv. The δD_(H_2O)and δ~(18) O(H_2O)values of the ore-forming fluids in quartz-sulfide episode vary from-112‰ to-76‰, and 11.0‰ to 1.0‰, respectively. All these above observations reveal that the early ore-forming fluids are magmatic in origin, and characterized by high temperature and moderate to high salinity, and gradually evolve to low temperature, low salinity meteoric water. The Huoshenmiao Mo δeposit is associated with the magmatism event induced by the protracted subduction of the Izanagi plate beneath the eastern China continent. The δecrease in temperature, salinity and f(O_2), as well as change of p H δue to boiling and fluid-rock interaction, are the main factors controlling Mo δeposition.
The Huoshenmiao δeposit is Mo skarn δeposit, located in the western part of the Luanchuan ore δistrict.Mineralization process can be δivided into a skarn and a quartz-sulfide episodes with six stages: prograde(I), retrograde(II), quartz-K-feldspar(III), quartz-molybdenite(IV), quartz-pyrite(V), and quartzcalcite(VI). A combined study of geochronology, fluid inclusion(FI), and stable isotopes was conducted to constrain the mineralization age, source of ore materials, as well as the origin and evolution of the ore-forming fluids. Molybdenite Ree Os δating indicates that the δeposit was formed in the Late Jurassic(~145 Ma). The δ~(34)S values of sulfides range from 3.0‰ to 7.1‰, implying that the ore materials in the δeposit are magmatic in origin. Three types and six subtypes of FIs are δistinguished, namely, aqueous two-phase(W_1-and W_2-type), δaughter mineral-bearing multiphase(S_1-and S_2-type), and CO_2-bearing three-phase(C_1-and C_2-type). In stages I and II, the W_1-type FIs δisplay homogenization temperatures(Th) from 496°C to >600°C, with salinities of 14.9-18.3 wt.% NaCl eqv. The FIs in stages III, IV and early stage V composed of coeval S-, C-and W-types, respectively homogenize at similar Th, suggesting the occurrence of boiling. The W1-type FIs in late stage V and stage VI, yield Th of 102-406°C and salinities of 0-4.7 wt.% NaCl eqv. The δD_(H_2O)and δ~(18) O(H_2O)values of the ore-forming fluids in quartz-sulfide episode vary from-112‰ to-76‰, and 11.0‰ to 1.0‰, respectively. All these above observations reveal that the early ore-forming fluids are magmatic in origin, and characterized by high temperature and moderate to high salinity, and gradually evolve to low temperature, low salinity meteoric water. The Huoshenmiao Mo δeposit is associated with the magmatism event induced by the protracted subduction of the Izanagi plate beneath the eastern China continent. The δecrease in temperature, salinity and f(O_2), as well as change of p H δue to boiling and fluid-rock interaction, are the main factors controlling Mo δeposition.
引文
Ames, L., Zhou, G.Z., Xiong, B.C., 1996. Geochronology and isotopic character of ultrahigh-pressure metamorphism with implications for collision of the SinoKorean cratons, central China. Tectonics 15(2), 472-489.
Audetat, A., 2010. Source and evolution of molybdenum in the porphyry Mo(-Nb)deposit at Cave Peak, Texas. Journal of Petrology 51,1739-1760.
Bali, E., Keppler, H., Audetat, A., 2012. The mobility of W and Mo in subduction zone fluids and the Mo-W-Th-U systematics of island arc magmas. Earth and Planetary Science Letters 351-352,195-207.
Bao, Z.W., Li, C.J., Qi, J.P., 2009. SHRIMP zircon U-Pb ages of the gabbro dyke in the Luanchuan Pb-Zn-Ag ore field, Qinlingorogen and its constraint on mineralization time. Acta Petrologica Sinica 25(11), 2951-2956(in Chinese with English abstract).
Bao, Z.W., Wang, Y.C., Zhao, T.P., Li, C.J., Gao, X.Y., 2014. Petrogenesis of the Mesozoic granites and Mo mineralization of the Luanchuan ore field in the East Qinling Mo mineralization belt, Central China. Ore Geology Reviews 57,132-153.
Bodnar, R.J., 1993. Revised equation and table for determining the freezing point depression of H2O-NaCl solutions. Geochimica et Cosmochimica Acta 57(3),683-684.
Bodnar, R.J., 2009. Heavy metals or punk rocks? Science 323, 724-725.
Buret, Y., Quadt, A., Heinrich, C., Selby, D., Walle, M., Peytcheva, I., 2016. From a long-lived upper-crustal magma chamber to rapid porphyry copper emplacement:reading the geochemistry of zircon crystals at Bajo de la Alumbrera(NW Argentina). Earth and Planetary Science Letters 450,120-131.
Campos, E., Touret, J.L.R., Nikogosian, I., 2006. Magmatic fluid inclusions from the Zaldivar deposit, northern Chile:the role of early metal bearing fluids in a porphyry copper system. Resource Geology 56,1-8.
Carten, R.B., White, W.H., Stein, H.J., 1993. High-grade granite-related molybdenum systems. In:Kirham, R.V., Sinclair, W.D., Thorpe, R.I., Duke, J.M.(Eds.), Mineral Deposit Modeling. Special Paper, 40. Geological Association of Canada,pp. 521-554.
Chen, J.F., Xie, Z., Liu, S.S., Li, X.M., Foland, K.A., 1995. Cooling age of DahieOrogen,China, determined by 40Ar-39Ar and fission track techniques. Science in China(B)38(6), 749-757.
Chen, X.D., 2012. Characteristics of Ore-forming Fluids and Metallogenesis in the Leimengou Porphyry Molybdenum Deposit, Western Henan Province. M.S.thesis. China University of Geosciences, Beijing, pp. 1-77(in Chinese with English abstract).
Chen, Y.J., Pirajno, F., Sui, Y.H., 2004. Isotope geochemistry of the Tieluping Ag deposit, Henan Province, China:a case study of orogenic Ag mineralization and related tectonic model. Mineralium Deposita 39, 560-575.
Cheng, Z.Y., Hu, J., Jiang, S.Y., Zhang, Z.Z., Dai, B.Z., Xiao, E., Wang, Y.F., 2013. Zircon U-Pb dating and Hf isotopes of the granites related to Yuchiling Mo deposit in Songxian county and their constraints on the metallogenetic age. Geological Journal of China Universities 19(3), 403-414(in Chinese with English abstract).
Clayton, Rn, O'neil, J.I., Mayeda, T.K., 1972. Oxygen isotope exchange between quartz and water. Journal of Geophysical Research 77, 3057-3067.
Collins, P.L.F., 1979. Gas hydrates in CO2-bearing fluid inclusions and the use of freezing data for estimation of salinity. Economic Geology 74,1435-1444.
Cooke, D.R., Deyell, C.L., Waters, P.J., Gonzales, R.I., Zaw, K., 2011. Evidence for magmatic-hydrothermal fluids and ore-forming processes in epithermal and porphyry deposits of the Baguio district, Philippines. Economic Geology 106,1399-1424.
Du, A.D., Zhao, D.M., Wang, S.X., Sun, D.Z., Liu, D.Y., 2001. Precise Re-Os dating for molybdenite by ID-NTIMS with carius tube sample preparation. Rock and Mineral Analysis 20(4), 247-252(in Chinese with English abstract).
Duan, S.G., Xue, C.J., Liu, G.Y., Yan, C.H., Feng, Q.W., Song, Y.W., Tu, Q.J., Gao, Y.B.,Gao, B.Y., 2010. Geology and sulfur isotope geochemistry of lead-zinc deposits in Luanchuan district, Henan province, China. Earth Science Frontiers 17(2),375-384(in Chinese with English abstract).
Gao, S., Luo, T.C., Zhang, B.R., Zhang, H.F., Han, Y.W., Zhao, Z.D., Hu, Y.K., 1998.Chemical composition of the continental crust as revealed by studies in East China. Geochimica et Cosmochimica Acta 62.1959-1975.
Gao, X.Y., Zhao, T.P., Chen, W.T., 2014. Petrogenesis of the early Cretaceous Funiushan granites on the southern margin of the North China Craton:implications for the Mesozoic geological evolution. Journal of Asian Earth Sciences94, 28-44.
Gao, Y., 2011. Geviogy, Geochemistry and Genesis of QianFanling Quartz-vein Mo Deposit in Songxian County, Western Henan Province. M.S. thesis. China University of Geosciences, Beijing, pp. 1-82(in Chinese with English abstract).
Gao, Y., Mao, J.W., Ye, H.S., Meng, F., Li, Y.F., 2015. A review of the geological characteristics and geodynamic setting of the late Early Cretaceous molybdenum deposits in the East Qinling-Dabie molybdenum belt, East China. Journal of Asian Earth Sciences 108, 81-96.
Gong, Q.J., Yu, C.W., Cen, K., Wang, Y.R., 2005. Experimental determination of MoO3and WO3 solubilities in supercritical fluids. Acta Petrologica Sinica 21(1),240-244(in Chinese with English abstract).
Guo, B., Zhu, L.M.,Li, B., Gong,H.J., Wang, J.Q, 2009. Zircon U-Pb age and Hf isotope composition of the Huashan and Heyu granite intrusions at the southern margin of North China Craton:implications for geodynamic setting. Acta Pelrologica Sinica 25(2), 265-281(in Chinese with English abstract).
He, Y.Q., Chen, F.Q., 2013. Geological characteristics and ore indicators of Huoshenmiao Mo deposit in Luanchuan county. Mining Technology 13(3), 115-118(in Chinese with English abstract).
Hedenquist, J.W., Lowenstern, J.B., 1994. The role of magmas in the formation of hydrothermal ore deposits. Nature 370, 519-527.
Hedenquist, J.W., Richards, J.P., 1998. The influence of geochemical techniques on the development of genetic models for porphyry copper deposits. Reviews in Economic Geology 10, 235-256.
Heinrich, C.A., 2007. Fluid-fluid interactions in magmatic-hydrothermal ore formation. Reviews in Mineralogy and Geochemistry 65, 363-387.
Henley, R.W., King, P.L., Wykes,J.L., Renggli, C.J., Brink, F.J., Clark, D.A., Troitzsch, U.,2015. Porphyry copper deposit formation by sub-volcanic sulphur dioxide flux and chemisorption. Nature Geoscience 8, 210-215.
Hoefs, J., 2009. Stable Isotope Geochemistry, sixth ed. Springer-Verlag, Berlin Heidelberg, pp. 71-73.
Huang, D.H., Wu, C.Y., Du, A.D., He, H.L., 1994. Re-Os isotope ages of molybdenum deposits in East Qinling and their significance. Mineral Deposits 13, 221-230(in Chinese with English abstract).
Huber, C., Bachmann, O., Vigneresse, J.L., Dufek, J., Parmigiani, A., 2012. A physical model for metal extraction and transport in shallow magmatic systems.Geochemistry, Geophysics, Geosystems 13(8), 1-18.
Keith, J.D., Christiansen, E.H., Maughan, D.T., Waite, K.A., 1998. The role of mafic alkaline magmas in felsic porphyry-Cu and Mo systems. In:Lentz, D.R.(Ed.),Mineralized Intrusion-related Skarn Systems:Mineralogical Association of Canada Short Course Series, 26, pp. 211-243.
Kesler, S.E., 2005. Ore-forming fluids. Elements 1,13-18.
Landtwing, M.R., Furrer, C., Redmond, P.B., 2010. The Bingham Canyon porphyry Cu-Mo-Au deposit.Ⅲ. Zoned copper-gold ore deposition by magmatic vapor expansion. Economic Geology 105, 91-118.
Li, N., Chen, Y.J., Ulrich, T., Lai, Y., 2012. Fluid inclusion study of the Wunugetu Cu-Mo deposit, Inner Mongolia, China. Mineralium Deposita 47, 467-482.
Li, S.G., Xiao, Y.L., Liou, D.L., Chen, Y.Z., Ge, N.J., Zhang, Z.Q., Sun, S.S., Cong, B.L.,Zhang R.Y,Hart, S.R., Wang, S.S., 1993. Collision of the North China and Yangtse blocks and formation of coesite-bearing eclogites:timing and processes.Chemical Geology 109(1-4), 70-89.
Li,Y.F., Mao, J.W., Bai, F.J., Li, J.P, He, Z., 2003. Re-Os isotopic dating of molybdenite in the Nannihu molybdenum(tungsten)ore field in the Eastern Qinling and its geological significance. Geological Review 49(6), 652-661(in Chinese with English abstract).
Li, Y.F., Mao,J.W., Hu, H.B., Guo, B.J., Bai, F.J., 2005. Geology, distribution, types and tectonic settings of Mesozoic molybdenum deposits in East Qinling area. Mineral Deposits 24(3), 292-304(in Chinese with English abstract).
Li, Z.K., 2012. Metallogenesis of the Silver-lead-zinc Deposits along the Southern Margin of the North China Craton. Ph.D. thesis. China University of Geosciences,Wuhan, pp. 1-197(in Chinese with English abstract).
Liu, G.Y., Yan, C.H., Xue, C.J., Zhang, D.H., Di,Y.J., Duan, S.G., Song, Y.W., Zeng,X.Y.,Wang, J.Z., Zhang, M.B., Lu, S.W., Yao, X.N., Lv, W.D., Zhao, R.J., Ding, H.Y.,Wang, F.Y., Lu, Y.H., He, Y.L., Ye, P., 2008. The Study of Metallogenic Regularities and Prospecting Direction of the Pb-Zn-Ag-Mo Ore Concentration Area in Southwestern Henan. Henan Institute of Geological Survey, Henan, pp. 1-303(in Chinese).
Lu, H.Z., 2014. Fluid inclusion petrography:a discussion. Geological Journal of China Universities 20(2), 177-184(in Chinese with English abstract).
Lu, H.Z., Fan, H.R., Ni, P., Ou, Y.X., Shen, K., Zhang, W.H., 2004. Fluid Inclusion. Science Press, Beijing, pp. 1-187(in Chinese).
Ludwig, K.R., 2004. Isoplot/ex, Version 3.0:a Geochronological Toolkit for Microsoft Excel. Berkeley Geochronology Center, Berkeley CA.
Luo, M.J., Zhang, F.M., Dong, Q.Y., Xu, Y.R., Li, S.M., Li, K.H., 1991. Molybdenum Deposits in China. Henan Press of Science and Technology, Zhengzhou, pp. 1-435(in Chinese).
Lv, W.D., Zhao, C.H., Sun, W.Z., Yan, J.S., 2006. Geological characteristics and genesis of Nannihu lead zinc polymetallic ore field in west Henan. Mineral Sources and Geology 20(3), 219-226(in Chinese with English abstract).
Maclnnis, M.S., Sanchez, P.L., Bodnar, R.J., 2012. Hokie Flincs_H2O-NaCl:a Microsoft Excel spread sheet for interpreting microthermometric data from fluid inclusions based on the PVTX properties of H2O-NaCl. Computers&Geosciences49, 334-337.
Mao, B., 2012. Geology, Geochemisty and Metallogenesis of the Yechangping Molybdenum Deposit, Western Henan Province. M.S. thesis. China University of Geosciences, Beijing, pp. 1-74(in Chinese with English abstract).
Mao, J.W., Pirajno, F., Xiang, J.F., Gao, J.J., Ye, H.S., Li, Y.F., Guo, B.J., 2011. Mesozoic molybdenum deposits in the east Qinling-Dabie orogenic belt:characteristics and tectonic settings. Ore Geology Reviews 43, 264-293.
Mao, J.W., Wang, Y.T., Li, H.M., Pirajno, F., Zhang, C.Q., Wang, R.T., 2008a. The relationship of mantle-derived fluids to gold metallogenesis in the Jiaodong Peninsula:evidence from D-O-C-S isotope systematics. Ore Geology Reviews33,361-381.
Mao, J.W., Xie, G.Q., Bierlein, F., Qv, W.J., Du, A.D., Ye, H.S., Piranjno, F., Li, H.M.,Guo, B.J., Li, Y.F., Yang, Z.Q., 2008b. Tectonic implications from Re-Os dating of Mesozoic molybdenum deposits in the East Qinling-Dabie orogenic belt. Geochimica et Cosmochimica Acta 72, 4607-4626.
Mao, J.W., Xie, G.Q., Pirajno, F., Ye, H.S., Wang, Y.B., Li, Y.F., Xiang, J.F., Zhao, H.J., 2010.Late Jurassic-Early Cretaceous granitoid magmatism in Eastern Qinling, centraleastern China:SHRIMP zircon U-Pb ages and tectonic implications. Australian Journal of Earth Sciences 57(1), 51-78.
Mao, J.W., Xie, G.Q., Zhang, Z.H., Li, X.F., Wang, Y.T., Zhang, C.Q., Li, Y.F., 2005.Mesozoic large-scale metallogenic pulses in North China and corresponding geodynamic settings. Acta Petrologica Sinica 21(1), 169-188(in Chinese with English abstract).
Mao,J.W., Ye, H.S., Wang, R.T., Dai, J.Z. Jian, W., Xiang,J.F., Zhou, K., Meng, F., 2009.Mineral deposit model of Mesozoic porphyry Mo and vein-type Pb-Zn-Ag ore deposit in the eastern Qinling, Central China and its implication for prospecting.Geological Bulletin China 28(1), 72-79.
Meinert, L.D., Dipple, G.M., Nicolescu, S., 2005. World skarn deposits. Economic Geology, 100th Anniversary Volume 299-336.
Meinert, L.D., Hedenquist, J.W., Satoh, H., 2003. Formation of anhydrous and hydrous skarn in Cu-Au ore deposits by magmatic fluids. Economic Geology 98,147-156.
Ni, P., Wang, G.G., Yu, W., Chen, H., Jiang, L.L., Wang, B.H., Zhang, H.D., Xu, Y.F., 2015.Evidence of fluid inclusions for two stages of fluid boiling in the formation of the giant Shapinggou porphyry Mo deposit, DabieOrogen, Central China. Ore Geology Reviews 65,1078-1094.
Ohmoto, H., 1972. Systematics of sulfide and carbon isotopes in hydrothermal ore deposits. Economic Geology 67, 551-578.
Ohmoto, H., 1986. Stable isotope geochemistry of ore deposits. In:Valley, J.W.,Taylor, H.P., O'Neil, J.R.(Eds.), Stable Isotopes in High Temperature Geological Process. Review in Mineralogy, 16, pp. 491-559.
Peng, H.J., Mao,J.W., Hou, L., Shu, Q.H., Zhang, C.Q., Liu, H., Zhou, Y.M., 2016. Stable isotope and fluid inclusion constraints on the source and evolution of ore fluids in the Hongniu-Hongshan Cu skarn deposit, Yunnan province, China. Economic Geology 111, 1369-1396.
Peng, P., Zhai, M.G., Ernst, R.E., Guo, J.H., Liu, F., Hu, B., 2008. A 1.78 Ga large igneous province in the North China Craton:the Xiong'er volcanic province and the North China dyke swarm. Lithos 101, 260-280.
Pettke, T., Oberli, F., Heinrich, C.A.,2010. The magma and metal source of giant porphyry-type ore deposits, based on lead isotope microanalysis of individual fluid inclusions. Earth and Planetary Science Letters 296, 267-277.
Pirajno, F., 2013. The Geology and Tectonic Settings of China's Mineral Deposits.Springer, Berlin, p. 679.
Rempel, K.U., Migdisov, A.A., Williams-Jones, A.E., 2006. The solubility of molybdenum in water vapour at elevated temperatures and pressures:implications for ore genesis. Geochimica et Cosmochimica Acta 70, 687-696.
Rempel, K.U., Williams-Jones, A.E., Migdisov, A.A., 2008. The solubility of molybdenum dioxide and trioxide in HCl-bearing water vapour at 350℃and pressures up to 160 bars. Geochimica et Cosmochimica Acta 72, 3074-3083.
Richards, J.P., 2011. Magmatic to hydrothermal metal fluxes in convergent and collided margins. Ore Geology Reviews 40,1-26.
Roedder, E., 1984. Fluid inclusions, reviews in mineralogy. Mineralogical Society of America 12, 1-644.
Rowley, D.B., Xue, F., Turker, R.D., Peng, Z.X., Baker, J., Davis, A., 1997. Ages of ultrahigh pressure metamorphism and protolith of orthogneisses from the eastern Dabieshan:U/Pb zircon geochemistry. Earth and Planetary Science Letters 151(3), 191-203.
Rusk, B.G., Reed, M.H., Dilles, J.H., 2008. Fluid inclusion evidence for magmatichydrothermal fluid evolution in the porphyry copper-molybdenum deposit at Butte Montana. Economic Geology 103, 307-334.
Selby, D., Creaser, R.A., 2004. Macroscale NTIMS and microscale LA-MC-ICP-MS Re-Os isotopic analysis of molybdenite:testing spatial restrictions for reliable Re-Os age determinations, and implications for the decoupling of Re and Os within molybdenite. Geochimica et Cosmochimica Acta 68, 3897-3908.
Selby, D., Creaser, R.A., Hart, C.J.R., Rombach, C.S., Thompson,J.F.H., Smith, M.T.,Bakke, A.A., Goldfarb, R.J., 2002. Absolute timing of sulfide and gold mineralization:a comparison of Re-Osmolybdenite and Ar-Ar mica methods from the Tintina Gold Belt, Alaska. Geology 30, 791-794.
Shinohara, H., Hedenquist,J.W., 1997. Constraints on magma degassing beneath the Far Southeast porphyry Cu-Au deposit, Philippines. Journal of Petrology 38,1741-1752.
Sillitoe, R.H., 2010. Porphyry copper systems. Economic Geology 105, 3-41.
Smoliar, M.I., Walker, R.J., Morgan, J.W., 1996. Re-Os ages of group IIA, IIIA, IVA and VIB iron meteorites. Science 271,1099-1102.
Stefanova, E., Driesner, T., Zajacz, Z., 2014. Melt and fluid inclusions in hydrothermal veins:the magmatic to hydrothermal evolution of the Elatsite porphyry Cu-Au deposit, Bulgaria. Economic Geology 109,1359-1381.
Stein, H.J., Markey, R.J., Morgan, J.W., Hannah, J.L., Schersten, A., 2001. The remarkable Re-Os chronometer in molybdenite:how and why it works. Terra Nova 13, 479-486.
Stein, H.J., Schersten, A., Hannah, J., Markey, R., 2003. Subgrain-scale decoupling of Re and 1870s and assessment of laser ablation ICP-MS spot dating in molybdenite. Geochimica et Cosmochimica Acta 67, 3673-3686.
Sun, W.D., Huang, R.F., Li,H.,Hu, Y.B., Zhang, C.C., Sun, S.J., Zhang, L.P., Ding, X.,Li, C.Y., Zartman, R.E., Ling, M.X., 2015. Porphyry deposits and oxidized magmas.Ore Geology Reviews 65, 97-131.
Suzuki, K., Shimizu, H., Masuda, A., 1996. Re-Os dating of molybdenites from ore deposits in Japan:implication for the closure temperature of the Re-Os system for molybdenite and the cooling history of molybdenum ore deposits. Geochimica et Cosmochimica Acta 60, 3151-3159.
Taylor, H.P., 1997. Oxygen and hydrogen isotope relationships in hydrothermal mineral deposits. In:Barnes, H.L.(Ed.), Geochemistry of Hydrothermal Ore Deposits. J Wiley, New York, pp. 229-302.
Ulrich, T., Mavrogenes, J., 2008. An experimental study of the solubility of molybdenum in H2O and KCl-H2O solutions from 500℃to 800℃, and 150 to300 MPa. Geochimica et Cosmochimica Acta 72, 2316-2330.
Wang, C.M., Deng, J., Zhang, S.T., Ye, H.S., 2006. Endogentic metallogenic system of Nannihu Mo-W-Cu-Pb-Zn-Ag-Au ore-forming area. Geological Science and Technology Information 25(6), 47-52(in Chinese with English abstract).
Wang, G.W., Li, R.X., Carranza,E.J.M., Zhang, S.T., Yan, C.H., Zhu, Y.Y., Qu, J.N.,Hong, D.M., Song, Y.W., Han, J.W., Ma, Z.B., Zhang, H., Yang, F., 2015. 3D geological modeling for prediction of subsurface Mo targets in the Luanchuan district, China. Ore Geology Reviews 71, 592-610.
Wang, S., Ye, H.S., Yang, Y.Q., Zhang, X.K., Su, H.M., Yang, C.Y., 2016. Zircon U-Pb chronology, geochemistry and Hf isotopic compositions of the Huoshenmiao intrusion, Western Henan. Earth Science-Journal of China University of Geosciences 41(2), 293-316(in Chinese with English abstract).
Wang, S., 2016. Genesis of the Huoshenmiao Mo Deposit, Luanchuan County, Henan Province. M.S. thesis. China University of Geosciences, Beijing, pp. 1-102(in Chinese with English abstract).
Wang, X.L., Jiang,S.Y., Dai, B.Z., Griffin,W., Dai, M.N., Yang, Y.H., 2011a. Age,geochemistry and tectonic setting of the Neoproterozoic(ca. 830 Ma)gabbros on the southern margin of the North China Craton. Precambrian Research 190,35-47.
Wang, X.X., Wang, T., Qi, Q.J., Li, C., 2011b. Temporal-spatial variations, origin and their tectonic significance of the Late Mesozoic granites in the Qinling, Central China. Actor Petrologica Sinica 27(6), 1573-1593(in Chinese with English abstract).
Wang, Z.M., Ren, J.G., Zhang, J.F., Ding, G.M., 2013. Geology and sulphur geochemistry of Yechangping molybdenum deposit, western Henan. Mineral Exploration4(3), 283-288(in Chinese with English abstract).
Wu, G., Chen, Y.C., Li, Z.Y., Liu, J., Yang, X.S., Qiao, C.J., 2014. Geochronology and fluid inclusion study of the Yinjiagou porphyry-skarn Mo-Cu-pyrite deposit in the East Qinling orogenic belt, China. Journal of Asian Earth Sciences 79, 585-607.
Xiang, J.F., Mao, J.W., Pei, R.F., Ye, H.S., Wang, C.Y., Tian,Z.H., Wang, H.L., 2012a. New geochronological data of granites and ores from the Nannihu-Sandaozhuang Mo(W)deposit. Geology in China 39(2), 258-273(in Chinese with English abstract).
Xiang, J.F., Pei, R.F., Ye, H.S., Wang, C.Y., Tian, Z.H., 2012b. Source and evolution of the ore-forming fluid in the Nannihu-Sandaozhuang Mo(W)deposit:constraints from C-H-O stable isotope data. Geology in China 39(6), 1778-1789(in Chinese with English abstract).
Xin, Z.G., 2010. Geological characteristics and prospecting message of the Shijiazhuang Mo deposit in Luanchuan county. West-China Exploration Engineering 5,101-102(in Chinese with English abstract).
Xu, W.C., Pang, Z.S., Zhou, Q.M., Wang, X.H., Yang, G.Q., 2003. Metallogeny of silverlead-zinc polymetallic ores outside Nannihu molybdenum(tungsten)ore field,Luanchuan County, Henan Province and its prospective. Mineral Resources and Geology 17,198-202(in Chinese with English abstract).
Xu, Z.W., Qiu, J.S., Ren, Q.J., Yang, R.Y., 1995. Characteristic of Yanshsnian granites related to molybdenum-tungsten deposits in the southern part of Luanehuan county, Henan province. Acta Petrologica Sinica 11(4), 397-408(in Chinese with English abstract).
Xu, Z.W., Ren, Q.J., 1988. Characteristics of magmatic evolution of Shibaogou,Huoshenmiao and Daping granitoids in Luanchuan county, Henan province.Journal of Nanjing University(Earth Science Edition)1, 95-103(in Chinese with English abstract).
Yang, Q.L., Zhao, Z.F., Zheng, Y.F., 2012a. Modification of subcontinental lithospheric mantle above continental subduction zone:constraints from geochemistry of Mesozoic gabbroic rocks in southeastern North China. Lithos146-147,164-182.
Yang, R.Y., Xu, Z.W., Ren, Q.J., 1997. Ages and magma sources of Shibaogou and Huoshenmiao complexes in east Qinling. Bulletin of Mineralogy, Petrology and Geochemistry 16(1), 16-19(in Chinese with English abstract).
Yang, Y., Chen, Y.J., Zhang, J., Zhang, C., 2013. Ore geology, fluid inclusions and fourstage hydrothermal mineralization of the Shangfanggou giant Mo-Fe deposit in Eastern Qinling, central China. Ore Geology Reviews 55,146-161.
Yang, Y., Wang, X.X., Ke, C.H., Li, J.B., 2012b. Zircon U-Pb age, geochemistry and Hf isotopic compositions of Shibaogou granitoid intrusion in the Nannihu ore district, western Henan province. Geology in China 9(6), 1525-1542(in Chinese with English abstract).
Yang, Y.F., Li, N., Chen, Y.J., 2012c. Fluid inclusion study of the Nannihu giant porphyry Mo-W deposit, Henan Province, China:implications for the nature of porphyry ore-fluid systems formed in a continental collision setting. Ore Geology Reviews 46, 83-94.
Ye, H.S., Mao, J.W., Li, Y.F., Yan, C.H., Guo, B.J., Zhao, C.S., He, C.F., Zheng, R.F., Chen, L.,2006. Characteristics and metallogenic mechanism of Mo-W and Pb-Zn-Ag deposits in Nannihu ore field, western Henan province. Geoscience 20(1),165-174(in Chinese with English abstract).
Yue, K.F., He, Y., Dong, Z.X., Zhang, W.P., 2006. Molybdenum content of mantlederived rocks from South China block and southern margin of North China Craton in eastern China and its implications. Geochimica 35(4), 333-345(in Chinese with English abstract).
Zhang, D.H., 1997. Overview of research on the ore depositional mechanisms in the ore-forming fluid. Geological Science and Technology Information 16(3),53-58(in Chinese with English abstract).
Zhang, J., Ye, H.S., Zhou, K., Meng, F., 2014. Processes of ore genesis at the worldclass Yuchiling molybdenum deposit, Henan province, China. Journal of Asian Earth Sciences 79, 666-681.
Zhang, L., Audetat, A., Dolejs, D., 2012. Solubility of molybdenite(MoS2)in aqueous fluids at 600-800℃, 200 MPa:a synthetic fluid inclusion study. Gcochimica et Cosmochimica Acta 77,175-185.
Zhang, Y.H., 2014. Late-Mesozoic Tectonic-magama Evolution and its Relationship with Mineralization in Luanchuan county. M.S. thesis. China University of Geosciences, Beijing, pp. 1-79(in Chinese with English abstract).
Zhao, G.C., Sun, M., Wilde, S.A., Li, S.Z., 2005. Late Archean to Paleoproterozoic evolution of the North China Craton:key issues revisited. Precambrian Research136, 177-202.
Zhao, G.C., Wilde, S.A., Cawood, P.A., Sun, M., 2001. Archean blocks and their boundaries in the North China Craton:lithological, geochemical, structural and P-T path constraints and tectonic evolution. Precambrian Research 107,45-73.
Zhao, T.P., 2000. Petrology and Geochemistry of the Proterozoic Volcanic Rocks of the Xiong'er Group in the Southern Margin of the North China Craton. Ph.D.thesis. Institute of Geology and Geophysics, CAGS, pp. 1-102(in Chinese with English abstract).
Zheng, Y.F., Chen, J.F., 2000. Stable Isotope Geochemistry. Science Press, Beijing,pp. 1-316(in Chinese).
Zheng, Y.F., Zhang, L., McClelland, W.C., Cuthbert, S., 2012. Processes in continental collision zones:preface. Lithos 136-139,1-9.
Zheng, Y.F., Zhao, Z.F., Chen, Y.X., 2013. Continental subduction channel processes:plate interface interacting during continental collision. Chinese Science Bulletin58(35), 4371-4377.
Zhou, K., 2008. Geology, Geochemisty and Metallogenesis of the Yuchiling Porphyry Molybdenum Deposit, Western Henan Province. Ph.D. thesis. China University of Geosciences, Beijing, pp. 1-78(in Chinese with English abstract).
Audetat, A., 2010. Source and evolution of molybdenum in the porphyry Mo(-Nb)deposit at Cave Peak, Texas. Journal of Petrology 51,1739-1760.
Bali, E., Keppler, H., Audetat, A., 2012. The mobility of W and Mo in subduction zone fluids and the Mo-W-Th-U systematics of island arc magmas. Earth and Planetary Science Letters 351-352,195-207.
Bao, Z.W., Li, C.J., Qi, J.P., 2009. SHRIMP zircon U-Pb ages of the gabbro dyke in the Luanchuan Pb-Zn-Ag ore field, Qinlingorogen and its constraint on mineralization time. Acta Petrologica Sinica 25(11), 2951-2956(in Chinese with English abstract).
Bao, Z.W., Wang, Y.C., Zhao, T.P., Li, C.J., Gao, X.Y., 2014. Petrogenesis of the Mesozoic granites and Mo mineralization of the Luanchuan ore field in the East Qinling Mo mineralization belt, Central China. Ore Geology Reviews 57,132-153.
Bodnar, R.J., 1993. Revised equation and table for determining the freezing point depression of H2O-NaCl solutions. Geochimica et Cosmochimica Acta 57(3),683-684.
Bodnar, R.J., 2009. Heavy metals or punk rocks? Science 323, 724-725.
Buret, Y., Quadt, A., Heinrich, C., Selby, D., Walle, M., Peytcheva, I., 2016. From a long-lived upper-crustal magma chamber to rapid porphyry copper emplacement:reading the geochemistry of zircon crystals at Bajo de la Alumbrera(NW Argentina). Earth and Planetary Science Letters 450,120-131.
Campos, E., Touret, J.L.R., Nikogosian, I., 2006. Magmatic fluid inclusions from the Zaldivar deposit, northern Chile:the role of early metal bearing fluids in a porphyry copper system. Resource Geology 56,1-8.
Carten, R.B., White, W.H., Stein, H.J., 1993. High-grade granite-related molybdenum systems. In:Kirham, R.V., Sinclair, W.D., Thorpe, R.I., Duke, J.M.(Eds.), Mineral Deposit Modeling. Special Paper, 40. Geological Association of Canada,pp. 521-554.
Chen, J.F., Xie, Z., Liu, S.S., Li, X.M., Foland, K.A., 1995. Cooling age of DahieOrogen,China, determined by 40Ar-39Ar and fission track techniques. Science in China(B)38(6), 749-757.
Chen, X.D., 2012. Characteristics of Ore-forming Fluids and Metallogenesis in the Leimengou Porphyry Molybdenum Deposit, Western Henan Province. M.S.thesis. China University of Geosciences, Beijing, pp. 1-77(in Chinese with English abstract).
Chen, Y.J., Pirajno, F., Sui, Y.H., 2004. Isotope geochemistry of the Tieluping Ag deposit, Henan Province, China:a case study of orogenic Ag mineralization and related tectonic model. Mineralium Deposita 39, 560-575.
Cheng, Z.Y., Hu, J., Jiang, S.Y., Zhang, Z.Z., Dai, B.Z., Xiao, E., Wang, Y.F., 2013. Zircon U-Pb dating and Hf isotopes of the granites related to Yuchiling Mo deposit in Songxian county and their constraints on the metallogenetic age. Geological Journal of China Universities 19(3), 403-414(in Chinese with English abstract).
Clayton, Rn, O'neil, J.I., Mayeda, T.K., 1972. Oxygen isotope exchange between quartz and water. Journal of Geophysical Research 77, 3057-3067.
Collins, P.L.F., 1979. Gas hydrates in CO2-bearing fluid inclusions and the use of freezing data for estimation of salinity. Economic Geology 74,1435-1444.
Cooke, D.R., Deyell, C.L., Waters, P.J., Gonzales, R.I., Zaw, K., 2011. Evidence for magmatic-hydrothermal fluids and ore-forming processes in epithermal and porphyry deposits of the Baguio district, Philippines. Economic Geology 106,1399-1424.
Du, A.D., Zhao, D.M., Wang, S.X., Sun, D.Z., Liu, D.Y., 2001. Precise Re-Os dating for molybdenite by ID-NTIMS with carius tube sample preparation. Rock and Mineral Analysis 20(4), 247-252(in Chinese with English abstract).
Duan, S.G., Xue, C.J., Liu, G.Y., Yan, C.H., Feng, Q.W., Song, Y.W., Tu, Q.J., Gao, Y.B.,Gao, B.Y., 2010. Geology and sulfur isotope geochemistry of lead-zinc deposits in Luanchuan district, Henan province, China. Earth Science Frontiers 17(2),375-384(in Chinese with English abstract).
Gao, S., Luo, T.C., Zhang, B.R., Zhang, H.F., Han, Y.W., Zhao, Z.D., Hu, Y.K., 1998.Chemical composition of the continental crust as revealed by studies in East China. Geochimica et Cosmochimica Acta 62.1959-1975.
Gao, X.Y., Zhao, T.P., Chen, W.T., 2014. Petrogenesis of the early Cretaceous Funiushan granites on the southern margin of the North China Craton:implications for the Mesozoic geological evolution. Journal of Asian Earth Sciences94, 28-44.
Gao, Y., 2011. Geviogy, Geochemistry and Genesis of QianFanling Quartz-vein Mo Deposit in Songxian County, Western Henan Province. M.S. thesis. China University of Geosciences, Beijing, pp. 1-82(in Chinese with English abstract).
Gao, Y., Mao, J.W., Ye, H.S., Meng, F., Li, Y.F., 2015. A review of the geological characteristics and geodynamic setting of the late Early Cretaceous molybdenum deposits in the East Qinling-Dabie molybdenum belt, East China. Journal of Asian Earth Sciences 108, 81-96.
Gong, Q.J., Yu, C.W., Cen, K., Wang, Y.R., 2005. Experimental determination of MoO3and WO3 solubilities in supercritical fluids. Acta Petrologica Sinica 21(1),240-244(in Chinese with English abstract).
Guo, B., Zhu, L.M.,Li, B., Gong,H.J., Wang, J.Q, 2009. Zircon U-Pb age and Hf isotope composition of the Huashan and Heyu granite intrusions at the southern margin of North China Craton:implications for geodynamic setting. Acta Pelrologica Sinica 25(2), 265-281(in Chinese with English abstract).
He, Y.Q., Chen, F.Q., 2013. Geological characteristics and ore indicators of Huoshenmiao Mo deposit in Luanchuan county. Mining Technology 13(3), 115-118(in Chinese with English abstract).
Hedenquist, J.W., Lowenstern, J.B., 1994. The role of magmas in the formation of hydrothermal ore deposits. Nature 370, 519-527.
Hedenquist, J.W., Richards, J.P., 1998. The influence of geochemical techniques on the development of genetic models for porphyry copper deposits. Reviews in Economic Geology 10, 235-256.
Heinrich, C.A., 2007. Fluid-fluid interactions in magmatic-hydrothermal ore formation. Reviews in Mineralogy and Geochemistry 65, 363-387.
Henley, R.W., King, P.L., Wykes,J.L., Renggli, C.J., Brink, F.J., Clark, D.A., Troitzsch, U.,2015. Porphyry copper deposit formation by sub-volcanic sulphur dioxide flux and chemisorption. Nature Geoscience 8, 210-215.
Hoefs, J., 2009. Stable Isotope Geochemistry, sixth ed. Springer-Verlag, Berlin Heidelberg, pp. 71-73.
Huang, D.H., Wu, C.Y., Du, A.D., He, H.L., 1994. Re-Os isotope ages of molybdenum deposits in East Qinling and their significance. Mineral Deposits 13, 221-230(in Chinese with English abstract).
Huber, C., Bachmann, O., Vigneresse, J.L., Dufek, J., Parmigiani, A., 2012. A physical model for metal extraction and transport in shallow magmatic systems.Geochemistry, Geophysics, Geosystems 13(8), 1-18.
Keith, J.D., Christiansen, E.H., Maughan, D.T., Waite, K.A., 1998. The role of mafic alkaline magmas in felsic porphyry-Cu and Mo systems. In:Lentz, D.R.(Ed.),Mineralized Intrusion-related Skarn Systems:Mineralogical Association of Canada Short Course Series, 26, pp. 211-243.
Kesler, S.E., 2005. Ore-forming fluids. Elements 1,13-18.
Landtwing, M.R., Furrer, C., Redmond, P.B., 2010. The Bingham Canyon porphyry Cu-Mo-Au deposit.Ⅲ. Zoned copper-gold ore deposition by magmatic vapor expansion. Economic Geology 105, 91-118.
Li, N., Chen, Y.J., Ulrich, T., Lai, Y., 2012. Fluid inclusion study of the Wunugetu Cu-Mo deposit, Inner Mongolia, China. Mineralium Deposita 47, 467-482.
Li, S.G., Xiao, Y.L., Liou, D.L., Chen, Y.Z., Ge, N.J., Zhang, Z.Q., Sun, S.S., Cong, B.L.,Zhang R.Y,Hart, S.R., Wang, S.S., 1993. Collision of the North China and Yangtse blocks and formation of coesite-bearing eclogites:timing and processes.Chemical Geology 109(1-4), 70-89.
Li,Y.F., Mao, J.W., Bai, F.J., Li, J.P, He, Z., 2003. Re-Os isotopic dating of molybdenite in the Nannihu molybdenum(tungsten)ore field in the Eastern Qinling and its geological significance. Geological Review 49(6), 652-661(in Chinese with English abstract).
Li, Y.F., Mao,J.W., Hu, H.B., Guo, B.J., Bai, F.J., 2005. Geology, distribution, types and tectonic settings of Mesozoic molybdenum deposits in East Qinling area. Mineral Deposits 24(3), 292-304(in Chinese with English abstract).
Li, Z.K., 2012. Metallogenesis of the Silver-lead-zinc Deposits along the Southern Margin of the North China Craton. Ph.D. thesis. China University of Geosciences,Wuhan, pp. 1-197(in Chinese with English abstract).
Liu, G.Y., Yan, C.H., Xue, C.J., Zhang, D.H., Di,Y.J., Duan, S.G., Song, Y.W., Zeng,X.Y.,Wang, J.Z., Zhang, M.B., Lu, S.W., Yao, X.N., Lv, W.D., Zhao, R.J., Ding, H.Y.,Wang, F.Y., Lu, Y.H., He, Y.L., Ye, P., 2008. The Study of Metallogenic Regularities and Prospecting Direction of the Pb-Zn-Ag-Mo Ore Concentration Area in Southwestern Henan. Henan Institute of Geological Survey, Henan, pp. 1-303(in Chinese).
Lu, H.Z., 2014. Fluid inclusion petrography:a discussion. Geological Journal of China Universities 20(2), 177-184(in Chinese with English abstract).
Lu, H.Z., Fan, H.R., Ni, P., Ou, Y.X., Shen, K., Zhang, W.H., 2004. Fluid Inclusion. Science Press, Beijing, pp. 1-187(in Chinese).
Ludwig, K.R., 2004. Isoplot/ex, Version 3.0:a Geochronological Toolkit for Microsoft Excel. Berkeley Geochronology Center, Berkeley CA.
Luo, M.J., Zhang, F.M., Dong, Q.Y., Xu, Y.R., Li, S.M., Li, K.H., 1991. Molybdenum Deposits in China. Henan Press of Science and Technology, Zhengzhou, pp. 1-435(in Chinese).
Lv, W.D., Zhao, C.H., Sun, W.Z., Yan, J.S., 2006. Geological characteristics and genesis of Nannihu lead zinc polymetallic ore field in west Henan. Mineral Sources and Geology 20(3), 219-226(in Chinese with English abstract).
Maclnnis, M.S., Sanchez, P.L., Bodnar, R.J., 2012. Hokie Flincs_H2O-NaCl:a Microsoft Excel spread sheet for interpreting microthermometric data from fluid inclusions based on the PVTX properties of H2O-NaCl. Computers&Geosciences49, 334-337.
Mao, B., 2012. Geology, Geochemisty and Metallogenesis of the Yechangping Molybdenum Deposit, Western Henan Province. M.S. thesis. China University of Geosciences, Beijing, pp. 1-74(in Chinese with English abstract).
Mao, J.W., Pirajno, F., Xiang, J.F., Gao, J.J., Ye, H.S., Li, Y.F., Guo, B.J., 2011. Mesozoic molybdenum deposits in the east Qinling-Dabie orogenic belt:characteristics and tectonic settings. Ore Geology Reviews 43, 264-293.
Mao, J.W., Wang, Y.T., Li, H.M., Pirajno, F., Zhang, C.Q., Wang, R.T., 2008a. The relationship of mantle-derived fluids to gold metallogenesis in the Jiaodong Peninsula:evidence from D-O-C-S isotope systematics. Ore Geology Reviews33,361-381.
Mao, J.W., Xie, G.Q., Bierlein, F., Qv, W.J., Du, A.D., Ye, H.S., Piranjno, F., Li, H.M.,Guo, B.J., Li, Y.F., Yang, Z.Q., 2008b. Tectonic implications from Re-Os dating of Mesozoic molybdenum deposits in the East Qinling-Dabie orogenic belt. Geochimica et Cosmochimica Acta 72, 4607-4626.
Mao, J.W., Xie, G.Q., Pirajno, F., Ye, H.S., Wang, Y.B., Li, Y.F., Xiang, J.F., Zhao, H.J., 2010.Late Jurassic-Early Cretaceous granitoid magmatism in Eastern Qinling, centraleastern China:SHRIMP zircon U-Pb ages and tectonic implications. Australian Journal of Earth Sciences 57(1), 51-78.
Mao, J.W., Xie, G.Q., Zhang, Z.H., Li, X.F., Wang, Y.T., Zhang, C.Q., Li, Y.F., 2005.Mesozoic large-scale metallogenic pulses in North China and corresponding geodynamic settings. Acta Petrologica Sinica 21(1), 169-188(in Chinese with English abstract).
Mao,J.W., Ye, H.S., Wang, R.T., Dai, J.Z. Jian, W., Xiang,J.F., Zhou, K., Meng, F., 2009.Mineral deposit model of Mesozoic porphyry Mo and vein-type Pb-Zn-Ag ore deposit in the eastern Qinling, Central China and its implication for prospecting.Geological Bulletin China 28(1), 72-79.
Meinert, L.D., Dipple, G.M., Nicolescu, S., 2005. World skarn deposits. Economic Geology, 100th Anniversary Volume 299-336.
Meinert, L.D., Hedenquist, J.W., Satoh, H., 2003. Formation of anhydrous and hydrous skarn in Cu-Au ore deposits by magmatic fluids. Economic Geology 98,147-156.
Ni, P., Wang, G.G., Yu, W., Chen, H., Jiang, L.L., Wang, B.H., Zhang, H.D., Xu, Y.F., 2015.Evidence of fluid inclusions for two stages of fluid boiling in the formation of the giant Shapinggou porphyry Mo deposit, DabieOrogen, Central China. Ore Geology Reviews 65,1078-1094.
Ohmoto, H., 1972. Systematics of sulfide and carbon isotopes in hydrothermal ore deposits. Economic Geology 67, 551-578.
Ohmoto, H., 1986. Stable isotope geochemistry of ore deposits. In:Valley, J.W.,Taylor, H.P., O'Neil, J.R.(Eds.), Stable Isotopes in High Temperature Geological Process. Review in Mineralogy, 16, pp. 491-559.
Peng, H.J., Mao,J.W., Hou, L., Shu, Q.H., Zhang, C.Q., Liu, H., Zhou, Y.M., 2016. Stable isotope and fluid inclusion constraints on the source and evolution of ore fluids in the Hongniu-Hongshan Cu skarn deposit, Yunnan province, China. Economic Geology 111, 1369-1396.
Peng, P., Zhai, M.G., Ernst, R.E., Guo, J.H., Liu, F., Hu, B., 2008. A 1.78 Ga large igneous province in the North China Craton:the Xiong'er volcanic province and the North China dyke swarm. Lithos 101, 260-280.
Pettke, T., Oberli, F., Heinrich, C.A.,2010. The magma and metal source of giant porphyry-type ore deposits, based on lead isotope microanalysis of individual fluid inclusions. Earth and Planetary Science Letters 296, 267-277.
Pirajno, F., 2013. The Geology and Tectonic Settings of China's Mineral Deposits.Springer, Berlin, p. 679.
Rempel, K.U., Migdisov, A.A., Williams-Jones, A.E., 2006. The solubility of molybdenum in water vapour at elevated temperatures and pressures:implications for ore genesis. Geochimica et Cosmochimica Acta 70, 687-696.
Rempel, K.U., Williams-Jones, A.E., Migdisov, A.A., 2008. The solubility of molybdenum dioxide and trioxide in HCl-bearing water vapour at 350℃and pressures up to 160 bars. Geochimica et Cosmochimica Acta 72, 3074-3083.
Richards, J.P., 2011. Magmatic to hydrothermal metal fluxes in convergent and collided margins. Ore Geology Reviews 40,1-26.
Roedder, E., 1984. Fluid inclusions, reviews in mineralogy. Mineralogical Society of America 12, 1-644.
Rowley, D.B., Xue, F., Turker, R.D., Peng, Z.X., Baker, J., Davis, A., 1997. Ages of ultrahigh pressure metamorphism and protolith of orthogneisses from the eastern Dabieshan:U/Pb zircon geochemistry. Earth and Planetary Science Letters 151(3), 191-203.
Rusk, B.G., Reed, M.H., Dilles, J.H., 2008. Fluid inclusion evidence for magmatichydrothermal fluid evolution in the porphyry copper-molybdenum deposit at Butte Montana. Economic Geology 103, 307-334.
Selby, D., Creaser, R.A., 2004. Macroscale NTIMS and microscale LA-MC-ICP-MS Re-Os isotopic analysis of molybdenite:testing spatial restrictions for reliable Re-Os age determinations, and implications for the decoupling of Re and Os within molybdenite. Geochimica et Cosmochimica Acta 68, 3897-3908.
Selby, D., Creaser, R.A., Hart, C.J.R., Rombach, C.S., Thompson,J.F.H., Smith, M.T.,Bakke, A.A., Goldfarb, R.J., 2002. Absolute timing of sulfide and gold mineralization:a comparison of Re-Osmolybdenite and Ar-Ar mica methods from the Tintina Gold Belt, Alaska. Geology 30, 791-794.
Shinohara, H., Hedenquist,J.W., 1997. Constraints on magma degassing beneath the Far Southeast porphyry Cu-Au deposit, Philippines. Journal of Petrology 38,1741-1752.
Sillitoe, R.H., 2010. Porphyry copper systems. Economic Geology 105, 3-41.
Smoliar, M.I., Walker, R.J., Morgan, J.W., 1996. Re-Os ages of group IIA, IIIA, IVA and VIB iron meteorites. Science 271,1099-1102.
Stefanova, E., Driesner, T., Zajacz, Z., 2014. Melt and fluid inclusions in hydrothermal veins:the magmatic to hydrothermal evolution of the Elatsite porphyry Cu-Au deposit, Bulgaria. Economic Geology 109,1359-1381.
Stein, H.J., Markey, R.J., Morgan, J.W., Hannah, J.L., Schersten, A., 2001. The remarkable Re-Os chronometer in molybdenite:how and why it works. Terra Nova 13, 479-486.
Stein, H.J., Schersten, A., Hannah, J., Markey, R., 2003. Subgrain-scale decoupling of Re and 1870s and assessment of laser ablation ICP-MS spot dating in molybdenite. Geochimica et Cosmochimica Acta 67, 3673-3686.
Sun, W.D., Huang, R.F., Li,H.,Hu, Y.B., Zhang, C.C., Sun, S.J., Zhang, L.P., Ding, X.,Li, C.Y., Zartman, R.E., Ling, M.X., 2015. Porphyry deposits and oxidized magmas.Ore Geology Reviews 65, 97-131.
Suzuki, K., Shimizu, H., Masuda, A., 1996. Re-Os dating of molybdenites from ore deposits in Japan:implication for the closure temperature of the Re-Os system for molybdenite and the cooling history of molybdenum ore deposits. Geochimica et Cosmochimica Acta 60, 3151-3159.
Taylor, H.P., 1997. Oxygen and hydrogen isotope relationships in hydrothermal mineral deposits. In:Barnes, H.L.(Ed.), Geochemistry of Hydrothermal Ore Deposits. J Wiley, New York, pp. 229-302.
Ulrich, T., Mavrogenes, J., 2008. An experimental study of the solubility of molybdenum in H2O and KCl-H2O solutions from 500℃to 800℃, and 150 to300 MPa. Geochimica et Cosmochimica Acta 72, 2316-2330.
Wang, C.M., Deng, J., Zhang, S.T., Ye, H.S., 2006. Endogentic metallogenic system of Nannihu Mo-W-Cu-Pb-Zn-Ag-Au ore-forming area. Geological Science and Technology Information 25(6), 47-52(in Chinese with English abstract).
Wang, G.W., Li, R.X., Carranza,E.J.M., Zhang, S.T., Yan, C.H., Zhu, Y.Y., Qu, J.N.,Hong, D.M., Song, Y.W., Han, J.W., Ma, Z.B., Zhang, H., Yang, F., 2015. 3D geological modeling for prediction of subsurface Mo targets in the Luanchuan district, China. Ore Geology Reviews 71, 592-610.
Wang, S., Ye, H.S., Yang, Y.Q., Zhang, X.K., Su, H.M., Yang, C.Y., 2016. Zircon U-Pb chronology, geochemistry and Hf isotopic compositions of the Huoshenmiao intrusion, Western Henan. Earth Science-Journal of China University of Geosciences 41(2), 293-316(in Chinese with English abstract).
Wang, S., 2016. Genesis of the Huoshenmiao Mo Deposit, Luanchuan County, Henan Province. M.S. thesis. China University of Geosciences, Beijing, pp. 1-102(in Chinese with English abstract).
Wang, X.L., Jiang,S.Y., Dai, B.Z., Griffin,W., Dai, M.N., Yang, Y.H., 2011a. Age,geochemistry and tectonic setting of the Neoproterozoic(ca. 830 Ma)gabbros on the southern margin of the North China Craton. Precambrian Research 190,35-47.
Wang, X.X., Wang, T., Qi, Q.J., Li, C., 2011b. Temporal-spatial variations, origin and their tectonic significance of the Late Mesozoic granites in the Qinling, Central China. Actor Petrologica Sinica 27(6), 1573-1593(in Chinese with English abstract).
Wang, Z.M., Ren, J.G., Zhang, J.F., Ding, G.M., 2013. Geology and sulphur geochemistry of Yechangping molybdenum deposit, western Henan. Mineral Exploration4(3), 283-288(in Chinese with English abstract).
Wu, G., Chen, Y.C., Li, Z.Y., Liu, J., Yang, X.S., Qiao, C.J., 2014. Geochronology and fluid inclusion study of the Yinjiagou porphyry-skarn Mo-Cu-pyrite deposit in the East Qinling orogenic belt, China. Journal of Asian Earth Sciences 79, 585-607.
Xiang, J.F., Mao, J.W., Pei, R.F., Ye, H.S., Wang, C.Y., Tian,Z.H., Wang, H.L., 2012a. New geochronological data of granites and ores from the Nannihu-Sandaozhuang Mo(W)deposit. Geology in China 39(2), 258-273(in Chinese with English abstract).
Xiang, J.F., Pei, R.F., Ye, H.S., Wang, C.Y., Tian, Z.H., 2012b. Source and evolution of the ore-forming fluid in the Nannihu-Sandaozhuang Mo(W)deposit:constraints from C-H-O stable isotope data. Geology in China 39(6), 1778-1789(in Chinese with English abstract).
Xin, Z.G., 2010. Geological characteristics and prospecting message of the Shijiazhuang Mo deposit in Luanchuan county. West-China Exploration Engineering 5,101-102(in Chinese with English abstract).
Xu, W.C., Pang, Z.S., Zhou, Q.M., Wang, X.H., Yang, G.Q., 2003. Metallogeny of silverlead-zinc polymetallic ores outside Nannihu molybdenum(tungsten)ore field,Luanchuan County, Henan Province and its prospective. Mineral Resources and Geology 17,198-202(in Chinese with English abstract).
Xu, Z.W., Qiu, J.S., Ren, Q.J., Yang, R.Y., 1995. Characteristic of Yanshsnian granites related to molybdenum-tungsten deposits in the southern part of Luanehuan county, Henan province. Acta Petrologica Sinica 11(4), 397-408(in Chinese with English abstract).
Xu, Z.W., Ren, Q.J., 1988. Characteristics of magmatic evolution of Shibaogou,Huoshenmiao and Daping granitoids in Luanchuan county, Henan province.Journal of Nanjing University(Earth Science Edition)1, 95-103(in Chinese with English abstract).
Yang, Q.L., Zhao, Z.F., Zheng, Y.F., 2012a. Modification of subcontinental lithospheric mantle above continental subduction zone:constraints from geochemistry of Mesozoic gabbroic rocks in southeastern North China. Lithos146-147,164-182.
Yang, R.Y., Xu, Z.W., Ren, Q.J., 1997. Ages and magma sources of Shibaogou and Huoshenmiao complexes in east Qinling. Bulletin of Mineralogy, Petrology and Geochemistry 16(1), 16-19(in Chinese with English abstract).
Yang, Y., Chen, Y.J., Zhang, J., Zhang, C., 2013. Ore geology, fluid inclusions and fourstage hydrothermal mineralization of the Shangfanggou giant Mo-Fe deposit in Eastern Qinling, central China. Ore Geology Reviews 55,146-161.
Yang, Y., Wang, X.X., Ke, C.H., Li, J.B., 2012b. Zircon U-Pb age, geochemistry and Hf isotopic compositions of Shibaogou granitoid intrusion in the Nannihu ore district, western Henan province. Geology in China 9(6), 1525-1542(in Chinese with English abstract).
Yang, Y.F., Li, N., Chen, Y.J., 2012c. Fluid inclusion study of the Nannihu giant porphyry Mo-W deposit, Henan Province, China:implications for the nature of porphyry ore-fluid systems formed in a continental collision setting. Ore Geology Reviews 46, 83-94.
Ye, H.S., Mao, J.W., Li, Y.F., Yan, C.H., Guo, B.J., Zhao, C.S., He, C.F., Zheng, R.F., Chen, L.,2006. Characteristics and metallogenic mechanism of Mo-W and Pb-Zn-Ag deposits in Nannihu ore field, western Henan province. Geoscience 20(1),165-174(in Chinese with English abstract).
Yue, K.F., He, Y., Dong, Z.X., Zhang, W.P., 2006. Molybdenum content of mantlederived rocks from South China block and southern margin of North China Craton in eastern China and its implications. Geochimica 35(4), 333-345(in Chinese with English abstract).
Zhang, D.H., 1997. Overview of research on the ore depositional mechanisms in the ore-forming fluid. Geological Science and Technology Information 16(3),53-58(in Chinese with English abstract).
Zhang, J., Ye, H.S., Zhou, K., Meng, F., 2014. Processes of ore genesis at the worldclass Yuchiling molybdenum deposit, Henan province, China. Journal of Asian Earth Sciences 79, 666-681.
Zhang, L., Audetat, A., Dolejs, D., 2012. Solubility of molybdenite(MoS2)in aqueous fluids at 600-800℃, 200 MPa:a synthetic fluid inclusion study. Gcochimica et Cosmochimica Acta 77,175-185.
Zhang, Y.H., 2014. Late-Mesozoic Tectonic-magama Evolution and its Relationship with Mineralization in Luanchuan county. M.S. thesis. China University of Geosciences, Beijing, pp. 1-79(in Chinese with English abstract).
Zhao, G.C., Sun, M., Wilde, S.A., Li, S.Z., 2005. Late Archean to Paleoproterozoic evolution of the North China Craton:key issues revisited. Precambrian Research136, 177-202.
Zhao, G.C., Wilde, S.A., Cawood, P.A., Sun, M., 2001. Archean blocks and their boundaries in the North China Craton:lithological, geochemical, structural and P-T path constraints and tectonic evolution. Precambrian Research 107,45-73.
Zhao, T.P., 2000. Petrology and Geochemistry of the Proterozoic Volcanic Rocks of the Xiong'er Group in the Southern Margin of the North China Craton. Ph.D.thesis. Institute of Geology and Geophysics, CAGS, pp. 1-102(in Chinese with English abstract).
Zheng, Y.F., Chen, J.F., 2000. Stable Isotope Geochemistry. Science Press, Beijing,pp. 1-316(in Chinese).
Zheng, Y.F., Zhang, L., McClelland, W.C., Cuthbert, S., 2012. Processes in continental collision zones:preface. Lithos 136-139,1-9.
Zheng, Y.F., Zhao, Z.F., Chen, Y.X., 2013. Continental subduction channel processes:plate interface interacting during continental collision. Chinese Science Bulletin58(35), 4371-4377.
Zhou, K., 2008. Geology, Geochemisty and Metallogenesis of the Yuchiling Porphyry Molybdenum Deposit, Western Henan Province. Ph.D. thesis. China University of Geosciences, Beijing, pp. 1-78(in Chinese with English abstract).
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |