Thermodynamic investigation of lime-enhanced molybdenite reduction using methane-containing gases

• Published in: Thermochimica acta Vol. 503; pp. 46 - 54
• Main Authors: Najafabadi, Samad Ghasemi, Abbasi, Mohammad Hasan, Saidi, Ali
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier B.V 2010; Elsevier
• Subjects: Applied sciences; Carbon deposition; Chemistry; Exact sciences and technology; General and physical chemistry; Lime; Metals. Metallurgy; Methane; Molybdenite; Phase equilibria; Production of metals; Production of non ferrous metals. Process materials; Pyrometallurgy; Reduction; Stability diagrams; Methane; Lime; Molybdenite; Carbon deposition; Reduction; Stability diagrams; Molybdenum Sulfides; Gas mixture; Ternary system; Phase diagram; Carbon; Chemical reduction; Thermodynamics; Calcium Oxides; Phase equilibrium
• ISSN: 0040-6031; 1872-762X
• DOI: 10.1016/j.tca.2010.03.006

Lime-enhanced molybdenite reduction (LEMR) with methane-containing gases has been thermodynamically studied. The reaction proceeds through the direct oxidation of MoS 2 by CaO to form intermediate molybdenum oxidized species, MoO 2 and CaMoO 4. The thermodynamics of Mo–O–C–H and Mo–Ca–O–C–H systems has been investigated instead of Mo–Ca–S–O–C–H system, as the sulfur is captured by calcium and forms a neutral compound (i.e. calcium sulfide). The role of reducing agent is the reduction of these oxidized species. Reduction of oxidized species by methane will yield Mo, Mo 2C or MoC. The thermodynamic investigation resulted in construction of stability diagrams of molybdenum compounds. These diagrams were constructed for CH 4–H 2, CH 4–H 2–Ar and CH 4–CO 2–H 2O gas mixtures. In addition to stability regions of Mo, Mo 2C and MoC, the carbon deposition area was also identified. The results showed that by using appropriate gas composition and temperature, different molybdenum-containing phases would be stable thermodynamically while soot formation can be avoided.