XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 259
Batchelor, A.R., Buttress, A.J., Jones, D.A., Katrib, J., Way,
D., Chenje, T., Stoll, D., Dodds, C., Kingman, S.W.
2017. Towards large scale microwave treatment of ores:
Part 2—Metallurgical testing. Minerals Engineering
111:5–24.
Batchelor, A.R., Dodds, C., Kingman, S.W., Chiasson, G.,
Holmes, T. 2022. Selective Heat Ore Treatment (SHOT).
Unpublished study for the Crush It! Challenge,
Canada: Natural Resources Canada.
Batchelor, A.R., Ferrari-John, R.S., Katrib, J., Udoduo,
O., A.J., Jones, D.A., Dodds, C., Kingman, S.W.
2016b. Pilot scale microwave sorting of porphyry cop-
per ores: Part 1—Laboratory investigations. Minerals
Engineering 98:303–327.
Batchelor, A.R., Ferrari-John, R.S., Dodds, C., Kingman,
S.W. 2016c. Pilot scale microwave sorting of por-
phyry copper ores: Part 2—Pilot plant trials. Minerals
Engineering 111:5–24.
Batchelor, A.R., Jones, D.A., Plint, S., Kingman, S.W.
2015. Deriving the ideal ore texture for microwave
treatment of metalliferous ores. Minerals Engineering
84:116–129.
Batchelor, A.R., Jones, D.A., Plint, S., Kingman, S.W.
2016a. Increasing the grind size for effective liberation
and flotation of a porphyry copper ore by microwave
treatment. Minerals Engineering 94:61–75.
Buttress, A.J., Katrib, J., Jones, D.A., Batchelor, A.R.,
Craig, D.A., Royal, T.A., Dodds, C., Kingman, S.W.
2017. Towards large scale microwave treatment of ores:
Part 1—Basis of design, construction and commission-
ing. Minerals Engineering 109:169–183.
Charikinya, E., Bradshaw, S.M. 2017. An experimental
study of the effect of microwave treatment on long
term bioleaching of coarse, massive zinc sulphide.
Hydrometallurgy 173:106–114.
Chen, T.T., Dutrizac, J.E., Haque, K.E., Wyslousil, W.,
Kashyap, S. 1984. The relative transparency of min-
erals to microwave radiation. Canadian Metallurgical
Quarterly 23(3):349–51.
Church, R.H., Webb, W.E., Salsman, J.B. 1988. Dielectric
properties of low-loss minerals. Volume 9194 of Report
of Investigations, US Bureau of Mines. US Department
of the Interior.
Engeco 2021. Mining Energy Consumption 2021. Report.
Singapore: Engeco Pty Ltd.
Giyani, B.F. 2023. Microwave treatment of ores. PhD dis-
sertation. Nottingham: The University of Nottingham.
Holmes, T., Craig, D., Batchelor, A.R., Dodds, C.,
Kingman, S.W., Legault, E., Whetton, M. 2020.
Selective Heat Ore Treatment: Shaking up the eco-
nomics of mineral recovery, in Proceedings of the 59th
Conference of Metallurgists, COM 2020. The Canadian
Institute of Mining, Metallurgy and Petroleum.
Jones, D.A., Kingman, S.W., Whittles, D.N., Lowndes,
I.S. 2005. Understanding microwave assisted breakage.
Minerals Engineering 18:659–669.
Jones, D.A., Kingman, S.W., Whittles, D.N., Lowndes,
I.S. 2007. The influence of microwave energy delivery
method on strength reduction in ore samples. Chemical
Engineering and Processing 46:291–299.
Kingman, S.W., Jackson, K., Bradshaw, S.M., Rowson,
N.A., Greenwood, R. 2004a. An investigation into the
influence of microwave treatment on mineral ore com-
minution. Powder Technology 146:176–184.
Kingman, S.W., Jackson, K., Cumbane, A., Bradshaw,
S.M., Rowson, N.A., &Greenwood, R. 2004b.
Recent developments in microwave-assisted com-
minution. International Journal of Mineral Processing
74(1–4):71–83.
Kingman, S.W., Vorster, W., Rowson, N.A. 2000a. The
effect of microwave radiation on the processing of
Palabora copper ore. Journal of the South African
Institute of Mining and Metallurgy 100:297–204.
Kingman, S.W., Vorster, W., Rowson, N.A. 2000b. The
influence of mineralogy on microwave assisted grind-
ing. Minerals Engineering 13:313–327.
McGill, W.L., Walkiewicz, J.W. 1987. Applications of
microwave energy in extractive metallurgy. Microwave
Power and Electromagnetic Energy 22(3):175–7.
McGil, S.L., Walkiewicz, J.W., Smyres, G.A. 1988. The
effect of power level on the microwave heating of
selected chemicals and minerals. Materials Research
Society Proceedings 124:247–52.
Sahyoun, C., Rowson, N., Kingman, S., Groves, L.,
Bradshaw, S. 2005. The influence of microwave pre-
treatment on copper flotation. Journal of the South
African Institute of Mining and Metallurgy 105:7–14.
Ure, A.D. 2017. Understanding the influence of mineralogy
and microwave energy input on the microwave treat-
ment of copper ores. PhD thesis. Nottingham, UK: The
University of Nottingham.
Walkiewicz, J.W., Kazonich, G., McGill, S.L. 1988.
Microwave heating characteristics of selected min-
erals and compounds. Minerals and Metallurgical
Engineering 5(1):39–42.
Batchelor, A.R., Buttress, A.J., Jones, D.A., Katrib, J., Way,
D., Chenje, T., Stoll, D., Dodds, C., Kingman, S.W.
2017. Towards large scale microwave treatment of ores:
Part 2—Metallurgical testing. Minerals Engineering
111:5–24.
Batchelor, A.R., Dodds, C., Kingman, S.W., Chiasson, G.,
Holmes, T. 2022. Selective Heat Ore Treatment (SHOT).
Unpublished study for the Crush It! Challenge,
Canada: Natural Resources Canada.
Batchelor, A.R., Ferrari-John, R.S., Katrib, J., Udoduo,
O., A.J., Jones, D.A., Dodds, C., Kingman, S.W.
2016b. Pilot scale microwave sorting of porphyry cop-
per ores: Part 1—Laboratory investigations. Minerals
Engineering 98:303–327.
Batchelor, A.R., Ferrari-John, R.S., Dodds, C., Kingman,
S.W. 2016c. Pilot scale microwave sorting of por-
phyry copper ores: Part 2—Pilot plant trials. Minerals
Engineering 111:5–24.
Batchelor, A.R., Jones, D.A., Plint, S., Kingman, S.W.
2015. Deriving the ideal ore texture for microwave
treatment of metalliferous ores. Minerals Engineering
84:116–129.
Batchelor, A.R., Jones, D.A., Plint, S., Kingman, S.W.
2016a. Increasing the grind size for effective liberation
and flotation of a porphyry copper ore by microwave
treatment. Minerals Engineering 94:61–75.
Buttress, A.J., Katrib, J., Jones, D.A., Batchelor, A.R.,
Craig, D.A., Royal, T.A., Dodds, C., Kingman, S.W.
2017. Towards large scale microwave treatment of ores:
Part 1—Basis of design, construction and commission-
ing. Minerals Engineering 109:169–183.
Charikinya, E., Bradshaw, S.M. 2017. An experimental
study of the effect of microwave treatment on long
term bioleaching of coarse, massive zinc sulphide.
Hydrometallurgy 173:106–114.
Chen, T.T., Dutrizac, J.E., Haque, K.E., Wyslousil, W.,
Kashyap, S. 1984. The relative transparency of min-
erals to microwave radiation. Canadian Metallurgical
Quarterly 23(3):349–51.
Church, R.H., Webb, W.E., Salsman, J.B. 1988. Dielectric
properties of low-loss minerals. Volume 9194 of Report
of Investigations, US Bureau of Mines. US Department
of the Interior.
Engeco 2021. Mining Energy Consumption 2021. Report.
Singapore: Engeco Pty Ltd.
Giyani, B.F. 2023. Microwave treatment of ores. PhD dis-
sertation. Nottingham: The University of Nottingham.
Holmes, T., Craig, D., Batchelor, A.R., Dodds, C.,
Kingman, S.W., Legault, E., Whetton, M. 2020.
Selective Heat Ore Treatment: Shaking up the eco-
nomics of mineral recovery, in Proceedings of the 59th
Conference of Metallurgists, COM 2020. The Canadian
Institute of Mining, Metallurgy and Petroleum.
Jones, D.A., Kingman, S.W., Whittles, D.N., Lowndes,
I.S. 2005. Understanding microwave assisted breakage.
Minerals Engineering 18:659–669.
Jones, D.A., Kingman, S.W., Whittles, D.N., Lowndes,
I.S. 2007. The influence of microwave energy delivery
method on strength reduction in ore samples. Chemical
Engineering and Processing 46:291–299.
Kingman, S.W., Jackson, K., Bradshaw, S.M., Rowson,
N.A., Greenwood, R. 2004a. An investigation into the
influence of microwave treatment on mineral ore com-
minution. Powder Technology 146:176–184.
Kingman, S.W., Jackson, K., Cumbane, A., Bradshaw,
S.M., Rowson, N.A., &Greenwood, R. 2004b.
Recent developments in microwave-assisted com-
minution. International Journal of Mineral Processing
74(1–4):71–83.
Kingman, S.W., Vorster, W., Rowson, N.A. 2000a. The
effect of microwave radiation on the processing of
Palabora copper ore. Journal of the South African
Institute of Mining and Metallurgy 100:297–204.
Kingman, S.W., Vorster, W., Rowson, N.A. 2000b. The
influence of mineralogy on microwave assisted grind-
ing. Minerals Engineering 13:313–327.
McGill, W.L., Walkiewicz, J.W. 1987. Applications of
microwave energy in extractive metallurgy. Microwave
Power and Electromagnetic Energy 22(3):175–7.
McGil, S.L., Walkiewicz, J.W., Smyres, G.A. 1988. The
effect of power level on the microwave heating of
selected chemicals and minerals. Materials Research
Society Proceedings 124:247–52.
Sahyoun, C., Rowson, N., Kingman, S., Groves, L.,
Bradshaw, S. 2005. The influence of microwave pre-
treatment on copper flotation. Journal of the South
African Institute of Mining and Metallurgy 105:7–14.
Ure, A.D. 2017. Understanding the influence of mineralogy
and microwave energy input on the microwave treat-
ment of copper ores. PhD thesis. Nottingham, UK: The
University of Nottingham.
Walkiewicz, J.W., Kazonich, G., McGill, S.L. 1988.
Microwave heating characteristics of selected min-
erals and compounds. Minerals and Metallurgical
Engineering 5(1):39–42.