Fluid overprints and mineralization of the Zhuguangshan granite-related U district in China: Recorded by cathodoluminescence textures and chemistry of quartz

• Published in: Ore geology reviews Vol. 173; p. 106256
• Main Authors: Gao, Shen, Wang, Yongjian, Zou, Xinyu, Vinis, Edward L., Huang, Liangliang, Tao, Yi, Xu, Jing, Qin, Kezhang, Qiu, Zhengjie
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.10.2024
• Subjects: Fluid overprints; Granite-related; Quartz textures; Trace elements; U mineralization; Zhuguangshan; Fluid overprints; U mineralization; Granite-related; Trace elements; Quartz textures; Zhuguangshan
• ISSN: 0169-1368
• DOI: 10.1016/j.oregeorev.2024.106256

[Display omitted] •The evolution of quartz from the magmatic to hydrothermal stages is discontinuous.•Ore stage quartz has distinctly CL, Mn and Al contents that differ from other stages.•Altered magmatic quartz developed by fluid-rock reactions at low temperatures.•Rimmed textures of hydrothermal quartz formed during U-bearing fluid overprints.•Quartz textures and chemical signatures can serve as indicators of U mineralization. Most high-grade U ores are mined from quartz veins hosted in granites. The veins formed at shallow depths during episodic hydrothermal activity, however, the evolution of multiple stage fluids is not well constrained. In this study, we collected 56 quartz samples from the world-class, granite-related, Zhuguangshan U district (>17,000 t U from seven deposits) in southern China. Their textures and compositions were analyzed using scanning electron microscope cathodoluminescence (SEM-CL, n = 98) and laser ablation-induction coupled plasma-mass spectrometry (LA–ICP–MS, n = 643). Four types of quartz were identified, including magmatic quartz, early hydrothermal euhedral quartz, ore stage hydrothermal quartz (U-rich), and late hydrothermal quartz. New quartz textures and chemical compositions show that the transition of early hydrothermal quartz from the magmatic to hydrothermal stages is discontinuous, unlike the continuous trend observed in most magmatic-hydrothermal systems. Ore stage quartz is CL dark (with a peak at 650 nm), occurs as rims on early barren quartz, and has high contents of Mn, Al, and Sb. Altered textures of magmatic quartz developed through fluid-rock reactions at low temperatures, while rimmed textures of hydrothermal quartz formed during subsequent late-stage U-bearing fluid events, which played a crucial role in U mineralization. Quartz in the Zhuguangshan U district has distinct features compared to other magmatic-hydrothermal systems that can guide exploration for high-grade ore in this, and perhaps other, granite-related U systems.