In situ mineral chemistry of chlorite in Donghua area, Dehua‐Youxi‐Yongtai ore district, Fujian Province, south‐east China: Elemental characteristics and their implications for exploration

As an ordinary alteration mineral in the process of fluid–rock interaction, chlorite (most especially its chemical composition) has the potential to become an effective tool to reveal the physicochemical conditions during alteration and help exploration. However, its elemental characteristics during the chloritization process are yet to be clearly understood. The Dehua‐Youxi‐Yongtai (DYY) ore district in south‐east China is one of the potential areas of gold and polymetallic deposits. Lying in the north‐west section of the DYY ore district, the Donghua area is notable for its remarkable metallogenic potential, and porphyry‐epithermal systems might have developed in the area. This study focuses on the elemental characteristics of chlorite in the Donghua area as footprints of the alteration process and mineralization vectoring. According to the geological features and occurrences, the chlorite from Donghua can be divided into two generations: (a) Chlorite I is closely related to chloritization developed in intrusive and volcanic rocks (Permian quartz monzobiorite and Jurassic volcanic rocks of Changlin Formation), and (b) chlorite II is accompanied by superimposed hydrothermal overprinting. The alteration process suggested by overprinting chlorite II can be regarded as almost coeval with the ca. 154–153 Ma magmatic event, and chlorite II is later than chlorite I generation. According to the geothermometry of the chlorite in Donghua, chlorite I might have crystallized on the temperature of 180–240°C with a peak of ~200°C, and the overprinting chlorite II might have experienced two episodes of hydrothermal/epithermal fluid pulsing. The mineral geochemistry of the trace elements in the two generations of the chlorite in Donghua shows different characteristics. The replacement of Mg2+ by Fe2+ plays an important role for ionic substitution in the octahedral position, especially for chlorite II. The other occasion might be Mg and Fe jointly entering the octahedral position as well as Mg‐ and Fe‐AlVI substitution mechanisms. The enrichment of Mg especially in chlorite II suggests low‐grade oxidation and acid conditions, which might be beneficial for the transportation of metallogenic substances. The obvious differences of Co and Ni are remarkable aspects of the trace elements of chlorite in Donghua, resulted by the ion substitution and function of different octahedral site preference energy. The mineral chemistry of chlorite II from Donghua can be helpful for targeting and exploration vectoring in the DYY ore district.

[1]  E. Çiftçi,et al.  Mineralogy, geochemistry, fluid inclusion, and stable sulfur isotope investigation of the Terziali shear-related orogenic gold deposit (Central Anatolia, Turkey): implications for ore genesis and mineral exploration , 2022, Arabian Journal of Geosciences.

[2]  E. Jowett,et al.  Fitting Iron and Magnesium into the Hydrothermal Chlorite Geothermometer , 2021, SSRN Electronic Journal.

[3]  Fan Xiao,et al.  Ore genesis of Qingyunshan Cu-Au deposit in the Dehua-Youxi area of Fujian Province, southeastern China: Constraints from U-Pb and Re-Os geochronology, fluid inclusions, and H-O-S-Pb isotope data , 2021 .

[4]  Xilin Zhao,et al.  Tectonic transition from subduction to retreat of the palaeo-Pacific plate: new geochemical constraints from the late Mesozoic volcanic sequence in eastern Fujian Province, SE China , 2020, Geological Magazine.

[5]  Guangfu Xing,et al.  Magmatism, geological setting, alteration, and metallogenic potential of Donghua area, Dehua County, Fujian Province, Southeast China: Insights from porphyry zircon U-Pb and pyrite Rb-Sr geochronology, geochemistry and remote sensing , 2020 .

[6]  Jing Tian,et al.  Chlorite as an exploration indicator for concealed skarn mineralization: Perspective from the Tonglushan Cu–Au–Fe skarn deposit, Eastern China , 2020 .

[7]  Yu Zhang,et al.  Chlorite chemistry of Tongshankou porphyry-related Cu–Mo–W skarn deposit, Eastern China: Implications for hydrothermal fluid evolution and exploration vectoring to concealed orebodies , 2020 .

[8]  Cooke,et al.  Using Mineral Chemistry to Aid Exploration: A Case Study from the Resolution Porphyry Cu-Mo Deposit, Arizona , 2020 .

[9]  Huayong Chen,et al.  Elemental behavior during chlorite alteration: New insights from a combined EMPA and LA-ICPMS study in porphyry Cu systems , 2020, Chemical Geology.

[10]  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.

[11]  Yu Zhang,et al.  Chlorite alteration in porphyry Cu systems: New insights from mineralogy and mineral chemistry , 2020 .

[12]  P. Ni,et al.  Geological, fluid inclusion, and H–O–S–Pb isotopic studies of the Xiaban epithermal gold deposit, Fujian Province, southeast China: Implications for ore genesis and mineral exploration , 2020 .

[13]  Junyi Pan,et al.  Alunite 40Ar/39Ar and Zircon U-Pb Constraints on the Magmatic-Hydrothermal History of the Zijinshan High-Sulfidation Epithermal Cu-Au Deposit and the Adjacent Luoboling Porphyry Cu-Mo Deposit, South China: Implications for Their Genetic Association , 2019, Economic Geology.

[14]  F. Xia,et al.  The Mineral Chemistry of Chlorites and Its Relationship with Uranium Mineralization from Huangsha Uranium Mining Area in the Middle Nanling Range, SE China , 2019, Minerals.

[15]  M. Santosh,et al.  40Ar/39Ar geochronology, fluid inclusions, and ore‐grade distribution of the Jiawula Ag–Pb–Zn deposit, NE China: Implications for deposit genesis and exploration , 2019, Geological Journal.

[16]  M. Santosh,et al.  Geochemistry and geochronology of the Dongyang gold deposit in southeast China: Constraints on ore genesis , 2019, Geological Journal.

[17]  Sheng‐Rong Li,et al.  LA-ICP-MS in situ analyses of the pyrites in Dongyang gold deposit, Southeast China: Implications to the gold mineralization , 2019, China Geology.

[18]  Yang Zhang,et al.  Mineralogical characteristics of silver minerals from the Dongyang Gold deposit, China: Implications for the evolution of epithermal metallogenesis , 2018, Journal of Geochemical Exploration.

[19]  Pete Hollings,et al.  Element transport and enrichment during propylitic alteration in Paleozoic porphyry Cu mineralization systems: Insights from chlorite chemistry , 2018, Ore Geology Reviews.

[20]  Junyi Pan,et al.  Mapping of fluid, alteration and soil geochemical anomaly as a guide to regional mineral exploration for the Dehua gold orefield of Fujian Province, SE China , 2018, Geochemistry: Exploration, Environment, Analysis.

[21]  D. Good,et al.  Controls on the chemistry of minerals in late-stage veins and implications for exploration vectoring tools for mineral deposits: An example from the Marathon Cu-Pd deposit, Ontario, Canada , 2018, Journal of Geochemical Exploration.

[22]  L. Shu,et al.  Appalachian-style multi-terrane Wilson cycle model for the assembly of South China: COMMENT , 2018, Geology.

[23]  P. Shen,et al.  Mineralogy of the Aktogai giant porphyry Cu deposit in Kazakhstan: Insights into the fluid composition and oxygen fugacity evolution , 2018 .

[24]  Junyi Pan,et al.  Geology, ore-forming fluid and genesis of the Qiucun gold deposit: Implication for mineral exploration at Dehua prospecting region, SE China , 2018, Journal of Geochemical Exploration.

[25]  M. Santosh,et al.  Petrology, geochemistry and zircon U–Pb geochronology of the Jurassic porphyry dykes in the Dehua gold field, Southeast China: Genesis and geodynamics , 2018 .

[26]  Chaohao Xu,et al.  Chlorite and epidote chemistry of the Yandong Cu deposit, NW China: Metallogenic and exploration implications for Paleozoic porphyry Cu systems in the Eastern Tianshan , 2017, Ore Geology Reviews.

[27]  Yan‐jing Chen,et al.  Geology, fluid inclusion and stable isotope study of the Yueyang Ag-Au-Cu deposit, Zijinshan orefield, Fujian Province, China , 2017 .

[28]  Xiaoli Shi,et al.  The assembly of Rodinia: The correlation of early Neoproterozoic (ca. 900 Ma) high-grade metamorphism and continental arc formation in the southern Beishan Orogen, southern Central Asian Orogenic Belt (CAOB) , 2017 .

[29]  P. Liu,et al.  An Early Cretaceous W-Sn deposit and its implications in southeast coastal metallogenic belt: Constraints from U-Pb, Re-Os, Ar-Ar geochronology at the Feie'shan W-Sn deposit, SE China , 2017 .

[30]  T. Yoneda,et al.  Mineralogical aspects of interstratified chlorite-smectite associated with epithermal ore veins: A case study of the Todoroki Au-Ag ore deposit, Japan , 2016, Clay Minerals.

[31]  J. Wilkinson,et al.  Element mobility during propylitic alteration in porphyry ore systems: a case study of the Oyu Tolgoi deposits, Mongolia , 2016 .

[32]  M. Santosh,et al.  Mineralogical and isotopic studies of base metal sulfides from the Jiawula Ag–Pb–Zn deposit, Inner Mongolia, NE China , 2016 .

[33]  J. Mao,et al.  Geology, geochronology, and Hf isotope geochemistry of the Longtougang skarn and hydrothermal vein Cu–Zn deposit, North Wuyi area, southeastern China , 2015 .

[34]  K. Randive,et al.  Chloritisation along the Thanewasna shear zone, Western Bastar Craton, Central India: Its genetic linkage to Cu–Au mineralisation , 2015 .

[35]  D. Beaufort,et al.  Chlorite and chloritization processes through mixed-layer mineral series in lowtemperature geological systems – a review , 2015, Clay Minerals.

[36]  Mustafa Kumral,et al.  A Windows program for chlorite calculation and classification , 2015, Comput. Geosci..

[37]  J. Gemmell,et al.  The chlorite proximitor: A new tool for detecting porphyry ore deposits , 2015 .

[38]  Shenghong Hu,et al.  "Wave" signal-smoothing and mercury-removing device for laser ablation quadrupole and multiple collector ICPMS analysis: application to lead isotope analysis. , 2015, Analytical chemistry.

[39]  M. Santosh,et al.  Metallogeny and craton destruction: Records from the North China Craton , 2014 .

[40]  M. Santosh,et al.  Metallogeny in response to lithospheric thinning and craton destruction: Geochemistry and U–Pb zircon chronology of the Yixingzhai gold deposit, central North China Craton , 2014 .

[41]  Xixi Zhao,et al.  New geochronological data from the Paleozoic and Mesozoic nappe structures, igneous rocks, and molybdenite in the North Wuyi area, Southeast China , 2012 .

[42]  G. Bignall,et al.  THE APPLICATION OF CHLORITE GEOTHERMOMETRY TO HYDROTHERMALLY ALTERED ROTOKAWA ANDESITE , ROTOKAWA GEOTHERMAL FIELD , 2011 .

[43]  R. Sillitoe Porphyry Copper Systems , 2010 .

[44]  A. Meunier,et al.  Application of chemical geothermometry to low-temperature trioctahedral chlorites , 2009 .

[45]  Shan Gao,et al.  In situ analysis of major and trace elements of anhydrous minerals by LA-ICP-MS without applying an internal standard , 2008 .

[46]  T. Armbruster,et al.  Incorporation of sodium into the chlorite structure: the crystal structure of glagolevite, Na(Mg,Al)6[Si3AlO10](OH,O)8 , 2004 .

[47]  O. Vidal,et al.  Exhumation paths of high‐pressure metapelites obtained from local equilibria for chlorite–phengite assemblages , 2000 .

[48]  A. Inoue,et al.  Formation of Clay Minerals in Hydrothermal Environments , 1995 .

[49]  D. Peacor,et al.  Formation of corrensite, chlorite and chlorite-mica stacks by replacement of detrital biotite in low-grade pelitic rocks , 1994 .

[50]  R. Rye The evolution of magmatic fluids in the epithermal environment; the stable isotope perspective , 1993 .

[51]  J. R. Walker,et al.  Chlorite Polytype Geothermometry , 1993 .

[52]  F. Werner Magma degassing and mineral deposition in hydrothermal systems along convergent plate boundaries , 1992 .

[53]  M. Cathelineau Cation site occupancy in chlorites and illites as a function of temperature , 1988, Clay Minerals.

[54]  W. Maclean,et al.  Systematics of chlorite alteration at the Phelps Dodge massive sulfide deposit, Matagami, Quebec , 1987 .

[55]  H. Kawahata,et al.  Compositional differences in chlorite from hydrothermally altered rocks and hydrothermal ore deposits , 1987 .

[56]  S. Scott,et al.  The composition of chlorite as a function of sulfur and oxygen fugacity; an experimental study , 1987 .

[57]  J. Walshe A six-component chlorite solid solution model and the conditions of chlorite formation in hydrothermal and geothermal systems , 1986 .

[58]  M. Cathelineau,et al.  A chlorite solid solution geothermometer the Los Azufres (Mexico) geothermal system , 1985 .

[59]  U. Haack Spurenelemente in Biotiten aus Graniten und Gneisen , 1969 .