Abstract
Coal seams can host numerous critical metals (e.g., lithium and rare earth elements), which are of great significance to modern industry. An Early Permian coal seam from the Qinshui Basin (northern China) was investigated and is characterized by an unusual enrichment of P-F-Sr, Li, Zr-Ta, and REY (rare earth elements and yttrium). Integrated petrological, geochemical, and mineralogical analyses were used to elucidate the enrichment mechanisms of several characteristic elements and critical metals in coal. The results show that these coal samples are significantly enriched in F (560 μg/g on average, coal basis) and Sr (602 μg/g on average, coal basis). Apatite is found to be the main carrier of P and Sr. Geochemical indicators (e.g., Sr/Ba) indicate peat deposition under marine-influenced conditions, which promoted early diagenetic precipitation of apatite and Sr-phosphates. The positive correlation between Li and paragonite (r = 0.68), together with strong correlations of Ta with Zr and Hf, suggests a mixed derivation from felsic volcanic materials. Moreover, the geological background, mineral assemblages, and discrimination diagrams, such as Al(2)O(3)/TiO(2)-Nb/Yb and Al(2)O(3)/TiO(2)-Zr/TiO(2), indicate episodic deposition of felsic volcanic ash combined with detritus derived from weathering of the Yanshan and Qinling Orogens, which are dominated by granitic and felsic volcanic rocks. Scanning electron microscope observations further suggest that hydrothermal activity subsequently redistributed these metals within the coal seam, as evidenced by the occurrence of vein carbonates (Sr-ankerite) and diaspore. This multistage history explains the concurrent P-F-Sr, Li, Zr-Ta, and REY enrichment in coal. This also highlights the potential of this coal seam as a critical-metal resource and offers a framework for exploring similar deposits.