Abstract
Vanadium-bearing shale as a strategic resource is an important raw material for extracting vanadium, and the mechanochemical activation can realize the vanadium extraction by full-wet leaching with green, low-carbon and high efficiency. Based on mineralogical research on mineral composition and distribution, mineral embedded grain size distribution, we employ a graded activation process. The mechanism of mechanochemical activation-enhanced dissolution of vanadium-bearing shale is revealed through the relationship between activation kinetics and vanadium leaching as well as the fluorine adsorption process on different minerals surfaces of vanadium-bearing shale. Vanadium-bearing shale is mainly composed of quartz, muscovite, calcite, pyrite, feldspar and apatite. Vanadium with 94.24% exists in muscovite, while the remaining 5.76% exists in oxide. Muscovite is predominantly closely associated with quartz, calcite and organic carbonaceous and tends to be enriched in fine grained, displaying fine disseminated granularity with 0.005-0.06 mm. The grindability order of vanadium-bearing shale is observed as follows: -3 to +2.5 mm < -2.5 to +2 mm < -2 to +1 mm < -1 to +0.6 mm. The activation process of different particle sizes were well evaluated by kinetic equations (R (2) = 0.99). The vanadium leaching efficiency has a positive linear relationship with the activation yield at the optimal leaching particle size with -0.6 mm. The vanadium leaching efficiency and activation time can be expressed by equation of η = γ (0) exp(-kt (n) )μ + ν. The mineral surface of vanadium-bearing shale has a good adsorption of F(-) (23.89 mg g(-1)) undergoing amorphous phenomena. The order of F(-) adsorption capacity is calcite, pyrite, dolomite, muscovite, feldspar, and quartz. The adsorption process of F(-) alters the surface potential on the vanadium-bearing shale, and the negative charge on the of muscovite surface increases, while that of pyrite and calcite decreases, which is conducive to the diffusion of H(+) to the surface of muscovite and away from pyrite and calcite. F(-) generates CaF(2) with the surface of calcite and FeF(3) with Fe(iii)-S on the surface of pyrite, hindering and slowing down the dissolution of calcite and pyrite. F(-) forms Al-F and Si-F bonds with Si and Al on the surface of muscovite, promoting the dissolution of muscovite.