Apatite texture and composition in the Tonglushan porphyry-related skarn system, eastern China: implications for mineral exploration
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[1] G. Rollinson,et al. A mineralogical investigation into the formation of ore-barren endoskarn: An example from the Tonglushan porphyry system, eastern China , 2023, Ore Geology Reviews.
[2] R. Hu,et al. Porphyry Cu fertility of eastern Paleo-Tethyan arc magmas: Evidence from zircon and apatite compositions , 2022, Lithos.
[3] P. Shen,et al. Hydrothermal apatite record of ore-forming processes in the Hatu orogenic gold deposit, West Junggar, Northwest China , 2022, Contributions to Mineralogy and Petrology.
[4] G. Beaudoin,et al. Performance of predictive supervised classification models of trace elements in magnetite for mineral exploration , 2022, Journal of Geochemical Exploration.
[5] Xinfu Zhao,et al. Apatite chemistry as a petrogenetic–metallogenic indicator for skarn ore-related granitoids: an example from the Daye Fe–Cu–(Au–Mo–W) district, Eastern China , 2022, Contributions to Mineralogy and Petrology.
[6] He‐Cai Niu,et al. Apatite fingerprints on the magmatic-hydrothermal evolution of the Daheishan giant porphyry Mo deposit, NE China , 2021, GSA Bulletin.
[7] Yue Wu,et al. Chlorine and sulfur evolution in magmatic rocks: A record from amphibole and apatite in the Tonglvshan Cu-Fe (Au) skarn deposit in Hubei Province, south China , 2021 .
[8] Shao‐Yong Jiang,et al. Apatite texture and trace element chemistry of carbonatite-related REE deposits in China: Implications for petrogenesis , 2021 .
[9] L. Warr. IMA–CNMNC approved mineral symbols , 2021, Mineralogical Magazine.
[10] Jing Tian,et al. Petrogenesis of Early Cretaceous granitoids and mafic microgranular enclaves from the giant Tonglushan Cu–Au–Fe skarn orefield, Eastern China , 2021, Lithos.
[11] B. McInnes,et al. Apatite Texture, Composition, and O-Sr-Nd Isotope Signatures Record Magmatic and Hydrothermal Fluid Characteristics at the Black Mountain Porphyry Deposit, Philippines , 2021, Economic Geology.
[12] M. Slobodník,et al. Trace Elements in Apatite as Genetic Indicators of the Evate Apatite-Magnetite Deposit, NE Mozambique , 2020, Minerals.
[13] Jun Yan,et al. Evaluating magmatic fertility of Paleo-Tethyan granitoids in eastern Tibet using apatite chemical composition and Nd isotope , 2020 .
[14] G. Bromiley. Do concentrations of Mn, Eu and Ce in apatite reliably record oxygen fugacity in magmas? , 2020, Lithos.
[15] Wei Zhang,et al. Geochronology and textural and compositional complexity of apatite from the mineralization-related granites in the world-class Zhuxi W-Cu skarn deposit: A record of magma evolution and W enrichment in the magmatic system , 2020 .
[16] Li‐Qiang Yang,et al. Halogens and trace elements of apatite from Late Mesozoic and Cenozoic porphyry Cu-Mo-Au deposits in SE Tibet, China: Constraints on magmatic fertility and granitoid petrogenesis , 2020 .
[17] F. Wall,et al. The origin and composition of carbonatite-derived carbonate-bearing fluorapatite deposits , 2020, Mineralium Deposita.
[18] Jing Tian,et al. Short wavelength infrared (SWIR) spectroscopy of phyllosilicate minerals from the Tonglushan Cu-Au-Fe deposit, Eastern China: New exploration indicators for concealed skarn orebodies , 2020 .
[19] Cooke,et al. Chlorite and Epidote Mineral Chemistry in Porphyry Ore Systems: A Case Study of the Northparkes District, New South Wales, Australia , 2020, Economic Geology.
[20] J. Baele,et al. Unravelling the processes controlling apatite formation in the Phalaborwa Complex (South Africa) based on combined cathodoluminescence, LA-ICPMS and in-situ O and Sr isotope analyses , 2020, Contributions to Mineralogy and Petrology.
[21] C. Hart,et al. Using zircon trace element composition to assess porphyry copper potential of the Guichon Creek batholith and Highland Valley Copper deposit, south-central British Columbia , 2020, Mineralium Deposita.
[22] P. Hollings,et al. Multi-stage arc magma evolution recorded by apatite in volcanic rocks , 2020, Geology.
[23] G. Beaudoin,et al. Trace Element Composition of Igneous and Hydrothermal Magnetite from Porphyry Deposits: Relationship to Deposit Subtypes and Magmatic Affinity , 2019, Economic Geology.
[24] M. Whitehouse,et al. Apatite as a tracer of the source, chemistry and evolution of ore-forming fluids: The case of the Olserum-Djupedal REE-phosphate mineralisation, SE Sweden , 2019, Geochimica et Cosmochimica Acta.
[25] Wei-dong Sun,et al. In situ elemental and Sr-O isotopic studies on apatite from the Xu-Huai intrusion at the southern margin of the North China Craton: Implications for petrogenesis and metallogeny , 2019, Chemical Geology.
[26] J. Baele,et al. Cathodoluminescence Applied to Ore Geology and Exploration , 2019, Ore Deposits.
[27] M. Reich,et al. Halogens, trace element concentrations, and Sr-Nd isotopes in apatite from iron oxide-apatite (IOA) deposits in the Chilean iron belt: Evidence for magmatic and hydrothermal stages of mineralization , 2019, Geochimica et Cosmochimica Acta.
[28] R. Seltmann,et al. Geochemical contrasts between Late Triassic ore-bearing and barren intrusions in the Weibao Cu–Pb–Zn deposit, East Kunlun Mountains, NW China: constraints from accessory minerals (zircon and apatite) , 2018, Mineralium Deposita.
[29] Shaoyong Jiang,et al. Using apatite to discriminate synchronous ore-associated and barren granitoid rocks: A case study from the Edong metallogenic district, South China , 2018, Lithos.
[30] R. Takahashi,et al. Testing the Plagioclase Discriminator on the GEOROC Database to Identify Porphyry‐Fertile Magmatic Systems in Japan , 2018 .
[31] Cooke,et al. Porphyry Indicator Minerals (PIMS) and Porphyry Vectoring and Fertility Tools (PVFTS) - indicators of mineralization styles and recorders of hypogene geochemical dispersion halos , 2017 .
[32] P. Boehnke,et al. Sulfur isotopic zoning in apatite crystals: A new record of dynamic sulfur behavior in magmas , 2017 .
[33] J. Wilkinson,et al. The effect of titanite crystallisation on Eu and Ce anomalies in zircon and its implications for the assessment of porphyry Cu deposit fertility , 2017 .
[34] Shaoyong Jiang,et al. In situ major and trace element analysis of amphiboles in quartz monzodiorite porphyry from the Tonglvshan Cu–Fe (Au) deposit, Hubei Province, China: insights into magma evolution and related mineralization , 2017, Contributions to Mineralogy and Petrology.
[35] J. Kynický,et al. Apatite in carbonatitic rocks: Compositional variation, zoning, element partitioning and petrogenetic significance , 2017 .
[36] A. Simon,et al. Co-variability of S6+, S4+, and S2− in apatite as a function of oxidation state: Implications for a new oxybarometer , 2017 .
[37] D. Harlov,et al. Mineralogy, chemistry, and fluid-aided evolution of the Pea Ridge Fe oxide-(Y + REE) deposit, southeast Missouri, USA , 2016 .
[38] C. McFarlane,et al. In situ elemental and isotopic analysis of fluorapatite from the Taocun magnetite-apatite deposit, Eastern China: Constraints on fluid metasomatism , 2016 .
[39] C. Hart,et al. Hydrothermal Alteration Revealed by Apatite Luminescence and Chemistry: A Potential Indicator Mineral for Exploring Covered Porphyry Copper Deposits , 2016 .
[40] L. A. Coogan,et al. Apatite Trace Element Compositions: A Robust New Tool for Mineral Exploration , 2016 .
[41] R. Hu,et al. Apatite trace element and halogen compositions as petrogenetic-metallogenic indicators: Examples from four granite plutons in the Sanjiang region, SW China , 2016 .
[42] J. Baele,et al. Fluorapatite in carbonatite-related phosphate deposits: the case of the Matongo carbonatite (Burundi) , 2016, Mineralium Deposita.
[43] B. Williamson,et al. Porphyry copper enrichment linked to excess aluminium in plagioclase , 2016 .
[44] Gus Gunn,et al. Evidence for dissolution-reprecipitation of apatite and preferential LREE mobility in carbonatite-derived late-stage hydrothermal processes , 2016 .
[45] A. Putnis,et al. Distribution of halogens between fluid and apatite during fluid-mediated replacement processes , 2015 .
[46] R. Ketcham. Technical Note: Calculation of stoichiometry from EMP data for apatite and other phases with mixing on monovalent anion sites , 2015 .
[47] J. Webster,et al. Magmatic Apatite: A Powerful, Yet Deceptive, Mineral , 2015 .
[48] D. Harlov. Apatite: A Fingerprint for Metasomatic Processes , 2015 .
[49] J. Gemmell,et al. The chlorite proximitor: A new tool for detecting porphyry ore deposits , 2015 .
[50] C. Hawkesworth,et al. Apatite: A new redox proxy for silicic magmas? , 2014 .
[51] P. Vasconcelos,et al. Longevity of magmatic–hydrothermal systems in the Daye Cu–Fe–Au District, eastern China with implications for mineral exploration , 2014 .
[52] Guiqing Xie,et al. Mineral compositions and fluid evolution of the Tonglushan skarn Cu–Fe deposit, SE Hubei, east-central China , 2012 .
[53] K. Qin,et al. Major and Trace Element Characteristics of Apatites in Granitoids from Central Kazakhstan: Implications for Petrogenesis and Mineralization , 2012 .
[54] D. Günther,et al. Determination of Reference Values for NIST SRM 610–617 Glasses Following ISO Guidelines , 2011 .
[55] J. Mao,et al. Zircon U–Pb geochronological and Hf isotopic constraints on petrogenesis of Late Mesozoic intrusions in the southeast Hubei Province, Middle–Lower Yangtze River belt (MLYRB), East China , 2011 .
[56] G. Beaudoin,et al. Discriminant diagrams for iron oxide trace element fingerprinting of mineral deposit types , 2011 .
[57] Xian‐Hua Li,et al. SIMS U–Pb zircon geochronology of porphyry Cu–Au–(Mo) deposits in the Yangtze River Metallogenic Belt, eastern China: Magmatic response to early Cretaceous lithospheric extension , 2010 .
[58] Changqian Ma,et al. Late Mesozoic magmatism from the Daye region, eastern China: U–Pb ages, petrogenesis, and geodynamic implications , 2009 .
[59] D. Harlov,et al. Fluorapatite-monazite relationships in granulite-facies metapelites, Schwarzwald, southwest Germany , 2007, Mineralogical Magazine.
[60] Yu Wang. The onset of the Tan–Lu fault movement in eastern China: constraints from zircon (SHRIMP) and 40Ar/39Ar dating , 2006 .
[61] R. Wirth,et al. An experimental study of dissolution–reprecipitation in fluorapatite: fluid infiltration and the formation of monazite , 2005 .
[62] L. Meinert,et al. The magmatic–hydrothermal transition—evidence from quartz phenocryst textures and endoskarn abundance in Cu–Zn skarns at the Empire Mine, Idaho, USA , 2004 .
[63] M. Dungan,et al. Anhydrite, pyrrhotite, and sulfur-rich apatite: tracing the sulfur evolution of an Oligocene andesite (Eagle Mountain, CO, USA) , 2002 .
[64] W. Griffin,et al. Apatite as an indicator mineral for mineral exploration: trace-element compositions and their relationship to host rock type , 2002 .
[65] U. Kempe,et al. Cathodoluminescence (CL) behaviour and crystal chemistry of apatite from rare-metal deposits , 2002, Mineralogical Magazine.
[66] T. Nijland,et al. Fluid-induced nucleation of (Y + REE)-phosphate minerals within apatite: Nature and experiment. Part I. Chlorapatite , 2002 .
[67] M. Fleet,et al. Site Preference of Rare Earth Elements in Hydroxyapatite [Ca10(PO4)6(OH)2] , 2000 .
[68] Yuanming Pan,et al. The Lower Changjiang (Yangzi/Yangtze River) metallogenic belt, east central China: intrusion- and wall rock-hosted Cu–Fe–Au, Mo, Zn, Pb, Ag deposits , 1999 .
[69] J. Tepper,et al. Complex zoning in apatite from the Idaho batholith: A record of magma mixing and intracrystalline trace element diffusion , 1999 .
[70] J. Dilles,et al. Sulfur evolution of oxidized arc magmas as recorded in apatite from a porphyry copper batholith , 1998 .
[71] P. Henderson,et al. Apatite paragenesis in the Bayan Obo REE-Nb-Fe ore deposit, Inner Mongolia, China , 1997 .
[72] Georges Boulon,et al. Accommodation of rare-earths and manganese by apatite , 1997 .
[73] Yu Liu,et al. Some aspects of the crystal-chemistry of apatites , 1993, Mineralogical Magazine.
[74] D. Burt,et al. Introduction; terminology, classification, and composition of skarn deposits , 1982 .
[75] J. Gross,et al. Apatite trace element geochemistry and cathodoluminescent textures—A comparison between regional magmatism and the Pea Ridge IOAREE and Boss IOCG deposits, southeastern Missouri iron metallogenic province, USA , 2020 .
[76] A. Roy-Garand. Characterization of apatite within the Mactung W (Cu,Au) skarn deposit, Northwest Territories : implication for the evolution of skarn fluids , 2019 .
[77] L. Meinert,et al. Skarn deposits of China , 2019 .
[78] J. Gemmell,et al. Porphyry indicator minerals and their mineral chemistry as vectoring and fertility tools , 2017 .
[79] Yongjun Lu,et al. Zircon Compositions as a Pathfinder for Porphyry Cu ± Mo ± Au Deposits , 2016 .
[80] Mao Mao,et al. Application of trace-element compositions of detrital apatite to explore for porphyry deposits in central British Columbia , 2016 .
[81] J. Mao,et al. Geochemical constraints on Cu–Fe and Fe skarn deposits in the Edong district, Middle–Lower Yangtze River metallogenic belt, China , 2015 .
[82] L. Meinert,et al. Skarn-porphyry transition: an example from the Antamina skarn, Peru , 2015 .
[83] Li Wei. Discussion on Regional Metal Mineral Deposit Model of Late Mesozoic Cu-Fe-Au Polymetallic Deposits in the Southeast Hubei Province , 2013 .
[84] R. Hervig,et al. Apatite as a monitor of late-stage magmatic processes at Volcán Irazú, Costa Rica , 2008 .
[85] JonN C. SronnnnR,et al. Variation of F and Cl X-ray intensity due to anisotropic diffusion in apatite during electron microprobe analysis , 2007 .
[86] JonN G. Ronsno. Coupled substitutions involving REEs and Na and Si in apatites in alkaline rocks from the Ilimaussaq intrusion , South Greenland , and the petrological implications * , 2007 .
[87] G. Dipple,et al. World Skarn Deposits , 2005 .
[88] D. Harlov,et al. Fluid-induced nucleation of (Y+REE)-phosphate minerals within apatite: Nature and experiment. Part II. Fluorapatite , 2003 .
[89] M. Fleet,et al. Compositions of the Apatite-Group Minerals: Substitution Mechanisms and Controlling Factors , 2002 .
[90] P. Candela,et al. Apatite in Igneous Systems , 2002 .
[91] Gabriel M. Filippelli,et al. The Effects of Manganese(II) And Iron(II) on the Cathodoluminescence Signal in Synthetic Apatite , 1993 .