Molybdenite Re-Os and Zircon U-Pb Isotopic Constraints on Gold Mineralization Associated with Fine-Grained Granite in the Xiawolong Deposit, Jiaodong Peninsula, East China

Molybdenite Re-Os and zircon U-Pb isotopic data are first obtained from the stockwork and disseminated-style gold-bearing ores and the fine-grained granite hosting these ores in the Xiawolong gold mine, respectively, which is located within the Muping-Rushan gold metallogenic belt, eastern Jiaodong Peninsula, so as to illustrate the genesis of gold mineralization and its implication for exploration. Four molybdenite samples yield a well-defined Re-Os isochron age of 118.4 +/- 2.5 Ma (2 sigma), which is identical to the weighted average Re-Os model age of 118 +/- 1.7 Ma (2 sigma). Integration of the new geochronologic data with those reported recently from the other gold mines in the Muping-Rushan gold metallogenic belt suggests that a discrete gold event occurred in Xiawolong ca. 4 m.y. older than that for the other gold mineralization at ca. 114 Ma in eastern Jiaodong. In addition, two fine-grained granite samples, measured using the LA-ICP-MS zircon U-Pb method, produce the first precise ages of 118 +/- 2 to 117 +/- 2 Ma (2 sigma), identical to the molybdenite Re-Os ages, within the margin of error and obtained in this study. The fine-grained granite has a similar lithology and emplacement age as those of the medium-grained monzogranite consisting of the marginal facies of the Sanfoshan batholith, and is considered to be the crystallization products of Sanfoshan granitic magma in the late stage. Combined with the previous S-Pb-D-O isotope, fluid inclusion and geological studies, which suggest that the ore-forming fluid of Xiawolong gold mineralization is from magmatic water, and the identification that the magnetite coexists with the gold-bearing pyrite and molybdenite in the gold ores, which indicates a high oxygen fugacity (fO2) of both the magma and resultant hydrothermal fluids, it is logical to infer that the Xiawolong gold deposit is genetically in relation to the Sanfoshan granitic magmatism, which is high in fO2 and rich in Au at the magmatic-hydrothermal transition stage, and the change in fO2 mostly likely makes a significant contribution to the precipitation of Au. This result reveals that the late-stage granitic magma with high fO2, which is crystallized into the fine-grained granite, probably is also rich in Au, except the W-Mo-Cu-Zn-U-Be-Li-Nb-Ta-Sn-Bi-elements. Therefore, based on the extensional tectonic regime for the early Cretaceous Jiaodong gold deposits, we propose that gold exploration in the Jiaodong should not only focus on the fault-hosted Au but also on the fine-grained granite-hosted Au around the apical portions of the late Early Cretaceous small-granitic intrusions with high fO2. This model could also be important for prospecting in other gold ore districts, which have a similar tectonic setting.