References
- Al-Harahsheh, M., 2005, “A fundamental investigation into the microwave assisted leaching of sulphide minerals,” Doctoral thesis, University of Nottingham.
- Al-Harahsheh, M., Al-Muhtaseb, A. H., and Magee, T. R. A., 2009, “Microwave drying kinetics of tomato pomace: effect of osmotic dehydration.” Chemical Engineering and Processing, 48. pp. 524–531.
- Al-Harahsheh, M., and Kingman, S. W., 2004, “Microwave-assisted leaching—a review.” Hydrometallurgy, 73(3). pp. 189–203.
- Bandosz, T. J., 2006, Activated carbon surfaces in environmental remediation, Academic press.
- Binner, J. G. P., and Cross, T. E., 1993, “Applications for microwave heating in ceramic sintering: challenges and opportunities.” Journal of Hardness Material,, 4. pp.177–185.
- Bradhurst, D., and Worner, H., 1990, “The application of microwave energy in mineral processing and pyrometallurgy in Australia.” TIZ-Fachberichte, 114(4). pp. 246–249.
- Bradshaw, S. M., Van Wyk, E. J., and De Swardt, J. B., 1998, “Microwave heating principles and the application to the regeneration of granular activated carbon.” Journal of the South African Institute of Mining and Metallurgy (South Africa), 98(4). pp. 201–210.
- Chen, G., Chang, X., Chen, J., Zhao, W., and Peng, J., 2015, “Investigation of BaCO3 powders synthesized by microwave homogeneous precipitation.” High Temperature Materials and Processes, 34(8).pp. 757–764.
- Church, R. H., Webb, W. E., and Salsman, J. B., 1988, Dielectric Properties of Low-Loss Minerals, Washington DC: US Department of the Interior, RI 9194.
- Dai, L., Peng, J., and Zhu, H., 2011, “Optimization of the process variables for making direct reduced iron by microwave heating using response surface methodology.,” Proceedings of TMS 2011. 2nd International Symposium on High-Temperature Metallurgical Processing, pp. 101–110.
- Das, S., Mukhopadhyay, A. K., Datta, S., and Basu, D., 2009, “Prospects of microwave processing: an overview.” Bulletin of Materials Science, 32(1). pp. 1–13.
- Duan, X., Srinivasakannan, C., Peng, J., Zhang, L., and Zheng-Yong, Z., 2011, “Preparation of activated carbon from Jatropha hull with microwave heating: optimization using response surface methodology.” Fuel Processing Technology, 92(3). pp. 394–400.
- Ford, J. D., and Pei, D. С. T., 1967, “High temperature chemical processing via microwave absorption.” Journal Microwave Power, 2(2). pp. 61–64.
- Gurrath, M., Kuretzky, T., Boehm, H. P., Okhlopkova, L. B., Lisitsyn, A. S., and Likholobov, V. A., 2000, “Palladium catalysts on activated carbon supports: influence of reduction temperature, origin of the support and pretreatments of the carbon surface.” Carbon, 38(8). pp. 1241–1255.
- Haque, K. E., 1999, “Microwave energy for mineral treatment processes—a brief review.” International Journal of Mineral Processing, 57(1). pp. 1–24.
- Henning, K. D., and Schäfer, S., 1993, “Impregnated activated carbon for environmental protection.” Gas Separation and Purification, 7(4). pp. 235–240.
- Huang, M., Peng, J., Yang, J., and Wang, J., 2006, “A new equation for the description of dielectric losses under microwave irradiation.” Journal of Physics D: Applied Physics, 39(10). pp. 2255.
- Ju, S., Lu, S., Zhang, L., Peng, J., Wang, Y., and Zheng, Q., 2012a, “Method for treating zinc hydrometallurgy dechlorinated copper residue through microwave continuous roasting,” Chinese patent application No.: 201210368375, 2012.09.28.
- Ju, S., Peng, J., Zhang, L., Lu, S., and Wang, Y., 2012b, “Microwave roasting dechlorination method for treating wet-method zinc and copper smelting slag,” Chinese patent application No.: 201210095568, 2012- 08-01.
- Katz, J. D., Blake, R. D., and Kenkre, V. M., 1991, Microwave enhanced diffusion (No. LA-UR-91-1559; CONF-910430–10), New Mexico: Los Alamos National Lab, American Ceramic Society.
- Kenkre, V. M., 1991, “Theory of microwave interactions with ceramic materials.” Ceramic Transactions, 21. pp. 69–80.
- Kingman, S. W., and Rowson, N. A., 1998, “Microwave treatment of minerals-a review.” Minerals Engineering, 11(11). pp. 1081–1087.
- Koleini, S. J., and Barani, K., 2012, Microwave heating applications in mineral processing, In The Development and Application of Microwave Heating, Prof, (W. Cao, Ed.), ISBN: 978-953-51-0835-1, InTech, 10.5772/45750. http://www.intechopen.com/books/the-development-and-application-of-microwave-heating/microwave-heating-applications-in-mineral-processing.
- Kumar, P., Sahoo, B. K., De, S., Kar, D. D., Chakraborty, S., and Meikap, B. C., 2010, “Iron ore grindability improvement by microwave pre-treatment.” Journal of Industrial and Engineering Chemistry, 16(5). pp. 805–812.
- Li, W., Peng, J., Zhang, L., Yang, K., Xia, H., Zhang, S., and Guo, S., 2009, “Preparation of activated carbon from coconut shell chars in pilot-scale microwave heating equipment at 60kW.” Waste Management, 29(2). pp. 756–760.
- Li, Z., Zhang, L., Ma, A., Peng, J., Li, J., and Liu, C., 2015, “Dechlorination of zinc oxide dust from Waelz Kiln by microwave roasting.” High Temperature Materials and Processes, 34(3). pp. 291–297.
- Liu, C., Xu, Y., and Hua, Y., 1990, “Application of microwave radiation to extractive metallurgy.” Chinese JMet Sciences Technological, 6. pp. 121–124.
- Liu, J., Peng, J., Zhang, L., Guo, S., Luo, H., Chen, G., Ying., L., and Wang, H., 2010, “Experimental investigation on new type of high temperature hot air system with microwave heating.” Modern Chemical Industry, 30(9). pp. 68–72. (Chinese)
- Lovás, M., Znamenáčková, I., Zubrik, A., Kováčová, M., and Dolinská, S., 2011, “The application of microwave energy in mineral processing–a review.” Acta Montanistica Slovaca, 16(2). pp. 137.
- Lu, M., Das, R. P., Li, W., Peng, J., and Zhang, L., 2013a, “Microwave mediated precipitation and aging of iron oxyhydroxides at low temperature for possible hydrometallurgical applications.” Hydrometallurgy, 134–135. pp. 110–116.
- Lu, M. N., Nikoloski, A. N., Singh, P., Parsonage, D., Das, R. P., Zhang, L. B., Li, W., and Peng, J. H., 2013b, Microwave-assisted preparation and physical characterisation of iron oxyhydroxides adsorbents for arsenic removal from aqueous solutions, In Advanced Materials Research, (J. Zeng, H. Zhu and J. Kong, Eds.), Vol. 634, pp. 249–253. Trans Tech Publications.
- Mazyck, D. W., and Cannon, F. S., 2000, “Overcoming calcium catalysis during the thermal reactivation of granular activated carbon: part I. Steam-curing plus ramped-temperature N2 treatment.” Carbon, 38(13). pp. 1785–1799.
- Metaxas, A. C., 1991, “Microwave heating.” Power Engineering Journal, 5(5). pp. 237–247.
- Mingos, D. M. P., and Baghurst, D. R., 1991, “Applications of microwave dielectric heating effects to synthetic problems in chemistry.” Chemical Society Review, 20(1). pp. 1–47.
- Mingos, D. M. P., and Baghurst, T. W., 1999, “Microwave processing: fundamentals and applications.” Composites Part A: Applied Science and Manufacturing, 30(9). pp. 1055–1071.
- Peng, Z., and Hwang, J. Y., 2015, “Microwave-assisted metallurgy.” International Materials Reviews, 60(1). pp. 30–63.
- Pickles, C. A., 2009, “Microwaves in extractive metallurgy: part 2-A review of applications.” Minerals Engineering, 22(13). pp. 1112–1118.
- Premaratne, W. A. P. J., and Rowson, N. A., 2015, “Microwave assisted dissolution of Sri Lankan Ilmenite: extraction and leaching kinetics of titanium and iron metals.” Journal of Science of the University of Kelaniya Sri Lanka, pp. 9, pp.1–14.
- Rosenholtz, J. L., and Dudley, T. S., 1936, The Dielectric Constant of Mineral Powders, Troy, NY:Rensselaer Polytechnic Institute.
- Salakjani, N. K., Nikoloski, A. N., and Singh, P., 2017, “Mineralogical transformations of spodumene concentrate from Greenbushes, Western Australia. Part 2: microwave heating.” Minerals Engineering, 100. pp. 191–199.
- Standish, N., and Worner, H., 1991, “Microwave application in the reduction of metal oxides with carbon.” Iron and Steel Maker, 18. pp. 59–61.
- Standish, N., Worner, H. K., and Gupta, G., 1990, “Temperature distribution in microwave heated iron ore-carbon composites.” Microwave Power Electromagnet Energy, 25(2). pp. 75–80.
- Sturm, G. S. J., Stefanidis, G. D., Verweij, M. D., Van Gerven, T. D. T., and Stankiewicz, A. I., 2010, “Design principles of microwave applicators for small-scale process equipment.” Chemical Engineering and Processing: Process Intensification, 49(9). pp. 912–922.
- Walker, G. M., and Weatherley, L. R., 2000, “Textile wastewater treatment using granular activated carbon adsorption in fixed beds.” Separation Science and Technology, 35(9). pp. 1329–1341.
- Walkiewicz, J. W., Clark, A. E., and McGill, S. L. 1991, “Microwave-assisted grinding.” IEEE Transactions on industry applications, 27(2). pp. 239–243.
- Xia, D. K., and Pickles, C. A., 2000, “Microwave caustic leaching of electric arc furnace dust.” Minerals Engineering, 13(1). pp. 79–94.
- Yang, J., Peng, J., Liu, B., and Luo, H., 2011, “The rapid preparation of MgO coating at low temperature by microwave liquid process.” Paint and Coatings Industry, 42(11). pp. 31–35. (Chinese)
- Yang, K., Li, S., Zhang, L., Peng, J., Chen, W., Xie, F., and Ma, A., 2016, Microwave Roasting, and leaching of an oxide-sulphide zinc ore. Hydrometallurgy, 166. pp. 243–251.
- Yang, K., Peng, J., Srinivasakannan, C., Zhang, L., Xia, H., and Duan, X., 2010, “Preparation of high surface area activated carbon from coconut shells using microwave heating.” Bioresource Technology, 101(15). pp. 6163–6169.
- Zuo, F., Badev, A., Saunier, S., Goeuriot, D., Heuguet, R., and Marinel, S., 2014, “Microwave versus conventional sintering: estimate of the apparent activation energy for densification of α-alumina and zinc oxide.” Journal of the European Ceramic Society, 34(12). pp. 3103–3110.