Effect of microwave radiation on processing characteristics of sulphide minerals in inert atmosphere

References

• Ford, J. D.; Pei, D. C. T. (1967) High temperature chemical processing via microwave absorption. J. Microwave Power, 2 (2): 61.
   Google Scholar
• Wong, D. (1975) Microwave dielectric constants of metal oxides at high temperature. MSc. Thesis, Univ. of Alberta, Canada.
   Google Scholar
• Chen, T. T.; Dutrizac, J. E.; Haque, K. E.; Wyslozil, W.; Kashyap, S. (1984) The relative transparency of minerals to microwave radiation. Canadian Metall. Quart., 23 (1): 349.
   Google Scholar
• Tinga, W. R. (1988) Microwave dielectric constants of metal oxides. Part 1. Electromagnetic Energy Reviews, 1 (5): 2.
   Google Scholar
• Tinga, W. R. (1989) Microwave dielectric constants of metal oxides. Part 2, Electromagnetic Energy Reviews, 2 (1): 349.
   Google Scholar
• Walkiewicz, J. W.; Kazonich, G.; McGill, S. L. (1988) Microwave heating characteristics of selected minerals and compounds. Mineral and Metallurgical Processing, 5 (1): 39.
   Google Scholar
• McGill, S. L.; Walkiewicz, J. W.; Smyres, G. A. (1988) The effect of power level on microwave heating of selected chemicals and minerals. Sutton, W.H., ed.; Mat. Res. Soc. Symp. Proc. Reno NV, M 4.6, Vol. 124.
   Google Scholar
• Chunpeng, L.; Yousheng, X.; Yixin, H. (1990) Application of microwave radiation to extractive metallurgy. Chin. J. Met. Sci. Technol., 6 (2): 121–124.
   Google Scholar
• Standish, N.; Worner, H. K.; Gupta, G. (1990) Temperature distribution in microwave heated iron ore-carbon composites. J. Microwave Power Electromagnet Energy, 25 (2): 75.
   Web of Science ®Google Scholar
• Walkiewicz, J. W.; Clark, A. E.; McGill, S. L. (1991) Microwave assisted grinding. IEEE Transactions on Industry Applications, 27 (2): 239.
   Web of Science ®Google Scholar
• Kingman, S. W.; Rowson, N. A. (1997) Applications of microwave radiation to enhance performance of mineral separation processes. Richard Mozley Memorial Symposium, Falmouth, England.
   Google Scholar
• Walkiewicz, J. W.; Lindroth, D. P.; Clark, A. E. (1993) Grindability of taconite rod mill feed enhanced by microwave induced cracking. SME Annual Meeting, Nevada: 1.
   Google Scholar
• Roussy, G.; Pearce, J. A. (1995) Foundations and industrial applications of microwave and radiofrequency fields, physical and chemical processes. Chapters 10-?12, Wiley: NJ.
   Google Scholar
• Wang, Y.; Forssberg, E. (2000) Microwave assisted comminution and liberation of minerals. Mineral Processing on the Verge of the 21st Century, Özbayoğlu, ed.; Balkema Publsihing: Rotterdam.
   Google Scholar
• Kingman, S. W.; Jackson, K.; Cumbane, A.; Bradshaw, S. M.; Rowson, N. A.; Greenwood, R. (2004) Recent developments in microwave-assisted comminution. Int. J. Miner. Process, 74:71.
   Web of Science ®Google Scholar
• Koleini, S. M. J.; Barani, K. (2008) The effect of microwave radiation upon grinding energy of an iron ore. Microwave Technology Conference, Cape Town, S. Africa.
   Google Scholar
• Koleini, S. M. J.; Barani, K.; Rezaei, B. (2012) The effect of microwave treatment upon dry grinding kinetics of an iron ore. Mineral Processing and Extractive Metallurgy Review Journal, 33 (2):159.
   Web of Science ®Google Scholar
• Fanslow. G. E.; Bluhm. D. D.; Nelson; S. O. (1980) Dielectric healing of mixtures containing coal and pyrite. Journal of Microwave Power, 15 (3): 187.
   Google Scholar
• Kelland, D. R.; Lai-Fook, M.; Maxwell, E.; Takayasu, M. (1988) HGMS coal desulfurization with microwave magnetization enhancement. IEEE Transaction on Magnetics, 24 (6): 2434.
   Web of Science ®Google Scholar
• Uslu, T.; Atalay, U. (2003) Microwave heating characteristics and microwave assisted magnetic enhancement of pyrite. International Mining Congress and Exhibition of Turkey-IMCET: 397.
   Google Scholar
• Standish, N.; Worner, H. K. (1991) Microwave application in the reduction of metal oxides with carbon. Iron and Steel Maker, 18 (5):59.
   Google Scholar
• Gomez, I.; Aguilar, J. A. (1995) Microwave for reduction of iron ore pellet by carbon. Mat. Res. Soc. Proc., 366: 347.
   Google Scholar
• Cook, N. P. (1986) Microwave Principles and Systems, Ch. 1; Prentice Hall: NY.
   Google Scholar
• Schiffmann, R. F. (1987) Microwave and dielectric drying. Majumder, A.S.; eds.; Handbook of Industrial Drying; Marcel Dekker: NY, p. 327.
   Google Scholar
• Doelling, M. K.; Jones, D. M.; Smith, R. A.; Nash, R. A. (1992) The development of a microwave fluid-bed processor: 1. Construction and qualification of a prototype laboratory unit. Pharmaceutical Research, 9 (11): 1487.
   PubMed Web of Science ®Google Scholar
• Matthes, S. A.; Farrell, R. F.; MacKie, A. J. (1983) A Microwave System for the Acid Dissolution of Metal and Mineral Samples; US Bureau of Mines: TRP 120.
   Google Scholar
• Kingston, H. M.; Jassie, L. B. (1985) Introduction to microwave sample preparation, theory and practice, Ch. 2 and 3. ACS professional reference book. Am. Chem. Soc.; Washington, DC, U.S.A.
   Google Scholar
• Kruesi, P. R.; Frahm, V. H. Process for the recovery of nickel, cobalt and manganese from their oxides and silicates. Canadian patent 1,160,057, US patent 4,311,520 and 4,324,582, 1982.
   Google Scholar
• Kruesi, W. H.; Kruesi, P. R. (1986) Microwave in laterite processing. Proceedings of CIM 25th Conf. of Metallurgists, Toronto.
   Google Scholar
• Peng, J.; Liu, C. (1992) The kinetics of ferric chloride leaching of sphalerite in the microwave field. Journal of China Nonferrous Metals, 2 (1): 46.
   Google Scholar
• Antonucci, V.; Correa, C. (1995) Sulphuric acid leaching of chalcopyrite concentrate assisted by application of microwave energy. Proc. of the Copper 95-Cobre 95, Int. Conf. Vol. 111, Santiago, Chile.
   Google Scholar
• Weian, D. (1997) Leaching behaviour of complex sulphide concentrate with ferric chloride by microwave irradiation. Rare Metals, 16 (2):152.
   Google Scholar
• Sahyoun, C.; Kingman, S. W.; Rowson, N. A. (2003) The effect of heat treatment on chalcopyrite. Phys. Sep. Sci. Eng., 12:23.
   Google Scholar
• Uslu, T.; Atalay, U.; Arol, A. I. (2003) Effect of microwave heating on magnetic separation of pyrite. Colloid Surf. A: Physicochem. Eng. Aspects (225): 161.
   Web of Science ®Google Scholar
• Waters, K. E.; Rowson, N. A.; Greenwood, R. W.; Williams, A. J. (2007) Characterising the effect of microwave radiation on the magnetic properties of pyrite. Sep. Purif. Technology, 46: 9.
   Web of Science ®Google Scholar
• Kingman, S. W.; Vorster, W.; Rowson, N. A. (2000) The effect of microwave radiation on the processing of Palabora copper ore. The Journal of South African Institute of Mining and Metallurgy, May/June: 197.
   Web of Science ®Google Scholar
• Berry, L. G. (ed.) (1974) Selected Powder Diffraction Data for Minerals, Data Book, Joint Committee on Powder Diffraction Standards, Pennsylvania.
   Google Scholar
• Can, N. M.; Bayraktar, I. (2007) Effect of microwave treatment on the flotation and magnetic separation properties of pyrite, chalcopyrite, galena and sphalerite. Minerals & Metallurgical Processing, 24 (3): 185.
   Web of Science ®Google Scholar
• Schwab, G. M.; Philinis, J. (1947) Reactions of iron pyrite: Its thermal decomposition, reduction by hydrogen and air oxidation. J. Am. Chem. Soc. ; 69(11): 2588.
   Web of Science ®Google Scholar
• Habashi, F.; Dugdale, R. (1969) The Effect of metallic iron on the thermal decomposition of chalcopyrite. Research Report, Research Division, The Anaconda Company; Tucson, AZ.
   Google Scholar
• Cathro, K. J. (1974) Recovery of copper from chalcopyrite by means of sulfur activation, cupric chloride leach and electrolysis. Proc. Australian Inst. Min. & Metall. ; 252: 1.
   Google Scholar
• Cathro, K. J. (1976) Recovery of copper from chalcopyrite by means of cupric chloride leach. Extractive Metallurgy of Copper. J. C. Yannupoulos, J.C. Agarwal, Eds.; AIME: New York, Vol. 2, p. 776.
   Google Scholar
• Robert C. Weast (Ed). (1985) CRC Handbook of Chemistry and Physics; CRC Press: Boca Raton, FL.
   Google Scholar