Porphyry Cu-Mo deposits are the most important sources of copper and molybdenum, and they are separately recovered by flotation. For the separation of Cu and Mo minerals (mostly chalcopyrite and molybdenite), the strategy of floating molybdenite while depressing chalcopyrite has been widely adopted by using chalcopyrite depressants, such as NaHS, Na₂S, and Nokes reagent. However, the conventionally used depressants can emit toxic H₂S gas when pulp pH decreased to < 9. In this study, thus, the application of microencapsulation (ME) technique using ferrous (Fe²⁺) and phosphate (H₂PO₄^–) ions to selectively depress the floatability of chalcopyrite by forming hydrophilic FePO₄ coating was investigated.

The results of ME treatments showed that FePO₄ coating was favorably formed on the surface of chalcopyrite compared to that of molybdenite due to the difference in their electrical resistivities. The electrical resistivity of chalcopyrite is by far lower than that of molybdenite, so the oxidation of Fe²⁺ to Fe³⁺ followed by FePO₄ precipitation occurred more actively on the surface of chalcopyrite than molybdenite. However, the results of single mineral flotation indicated that ME treatment depressed not only chalcopyrite (from ~70% to ~15%) but also molybdenite (from ~45% to ~6%). Although ME treatment also reduced the floatability of molybdenite, ~92% Mo could be recovered by utilizing emulsified kerosene. Flotation of chalcopyrite/molybdenite mixture confirmed that ME treatment improved the separation efficiency from 10.9% to 66.8%, indicating that ME treatment can be employed as a conditioning process for Cu-Mo flotation separation.