180 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
REFERENCES
Bai, G., Teng, W., Wang, X., Qin, J., Xu, P., and Li, P. 2010.
Alkali desilicated coal fly ash as substitute of bauxite
in lime-soda sintering process for aluminum produc-
tion. Transactions of Nonferrous Metals Society of China
20:169–175.
Blissett, R.S., and Rowson, N.A. 2012. A review of the
multi-component utilisation of coal fly ash. Fuel
97:1–23.
Cao, D., Selic, E., Herbell, J.-D., 2008. Utilization of fly
ash from coal-fired power plants in China. J. Zhejiang
Univ. Sci. A 9:681–687.
Ent, A. van der, Baker, A.J.M., Reeves, R.D., Pollard, A.J.,
and Schat, H. 2013. Hyperaccumulators of metal and
metalloid trace elements: Facts and fiction. Plant Soil
362:319–334.
Ent, A. van der, Echevarria, G., and Baker, A.J.M., eds.
2018. Agromining: Farming for Metals Extracting
Unconventional Resources Using Plants, Mineral Resource
Reviews. Cham: Springer International Publishing.
Reeves, R.D., Baker, A.J.M., Jaffré, T., Erskine, P.D.,
Echevarria, G., and Ent, A. van der, 2018. A global
database for plants that hyperaccumulate metal and
metalloid trace elements. New Phytologist 218:407–411.
Shemi, A., Mpana, R.N., Ndlovu, S., van Dyk, L.D.,
Sibanda, V., and Seepe, L. 2012. Alternative techniques
for extracting alumina from coal fly ash. Minerals
Engineering 34:30–37.
Voisin, P. 1992. Métallurgie extractive de l’aluminium.
Techniques de l’Ingénieur. Ref: v2-m2340, 30p.
Wei, C., Cheng, S., Zhu, F., Tan, X., Li, W., Zhang, P., and
Miao, S. 2018. Digesting high-aluminum coal fly ash
with concentrated sulfuric acid at high temperatures.
Hydrometallurgy 180:41–48.
REFERENCES
Bai, G., Teng, W., Wang, X., Qin, J., Xu, P., and Li, P. 2010.
Alkali desilicated coal fly ash as substitute of bauxite
in lime-soda sintering process for aluminum produc-
tion. Transactions of Nonferrous Metals Society of China
20:169–175.
Blissett, R.S., and Rowson, N.A. 2012. A review of the
multi-component utilisation of coal fly ash. Fuel
97:1–23.
Cao, D., Selic, E., Herbell, J.-D., 2008. Utilization of fly
ash from coal-fired power plants in China. J. Zhejiang
Univ. Sci. A 9:681–687.
Ent, A. van der, Baker, A.J.M., Reeves, R.D., Pollard, A.J.,
and Schat, H. 2013. Hyperaccumulators of metal and
metalloid trace elements: Facts and fiction. Plant Soil
362:319–334.
Ent, A. van der, Echevarria, G., and Baker, A.J.M., eds.
2018. Agromining: Farming for Metals Extracting
Unconventional Resources Using Plants, Mineral Resource
Reviews. Cham: Springer International Publishing.
Reeves, R.D., Baker, A.J.M., Jaffré, T., Erskine, P.D.,
Echevarria, G., and Ent, A. van der, 2018. A global
database for plants that hyperaccumulate metal and
metalloid trace elements. New Phytologist 218:407–411.
Shemi, A., Mpana, R.N., Ndlovu, S., van Dyk, L.D.,
Sibanda, V., and Seepe, L. 2012. Alternative techniques
for extracting alumina from coal fly ash. Minerals
Engineering 34:30–37.
Voisin, P. 1992. Métallurgie extractive de l’aluminium.
Techniques de l’Ingénieur. Ref: v2-m2340, 30p.
Wei, C., Cheng, S., Zhu, F., Tan, X., Li, W., Zhang, P., and
Miao, S. 2018. Digesting high-aluminum coal fly ash
with concentrated sulfuric acid at high temperatures.
Hydrometallurgy 180:41–48.