7
V. (2022) “Mine waste as a sustainable resource for
facing bricks,” Journal of Cleaner Production, 368,
133118. doi.org/10.1016/j.jclepro.2022.133118
[17] Ahmari, S., Zhang, L. (2012) “Production of eco-
friendly bricks from copper mine tailing through geo-
polimerization,” Construction and Building Materials,
pp. 323–331,
[18] Gitari, M. W., Akinyemi, S.A., Thobakgale, R.,
Ngoejana, P.C., Ramugondo, L., Matidza, M.,
Mhlongo, S.E., Dacosta, F.A., Nemapate, N. (2018)
“Physicochemical and Mineralogical Characterization
of Musina Mine Copper and New Union Gold Mine
Tailings: Implications for Fabrication of Beneficial
Geopolymeric Construction Materials,” Journal of
African Earth Sciences, pp. 218–228.
[19] Roy, S., Adhikari, G. R. (2007) “Use of gold mill
tailings in making bricks: A feasibility study,” Waste
Management &Research, pp. 475–482.
[20] Valdez, J., Aguilar, J., Sanchez, L. (2020) “Diseño
e implementación de un proceso alternativo para la
fabricación de ladrillos a partir de relaves mineros de
Oro,” Ingeniare. Rev. Chil. Ing., pp. 268–276.
[21] Benahsina, A., Taha, Y., Bouachera, R., Elomari,
M., Bennouna, M.A. (2021) “Manufacture and
Characterization of Fired Bricks from Gold Mine
Waste Rocks,” Minerals, 11, 695. doi.org/10.3390
/min11070695
[22] Wei, Z., Zhao, J., Wang, W., Yang, Y., Zhuang, S.,
Lu, T., Hou, Z. (2021) “Utilizing gold mine tail-
ings to produce sintered bricks,” Construction and
Building Materials. 282, 122655. doi.org/10.1016
/j.conbuildmat.2021.122655
[23] Kuranchie, F. A., Shukla, S. K., Habibi, D. (2016)
“Utilisation of iron ore mine tailings for the produc-
tion of geopolymer bricks,” International Journal of
Mining, Reclamation and Environment, pp. 1–24.
[24] Li, R., Zhou, Y., Li, C., Li, S., Huang, Z. (2019)
“Recycling of industrial waste iron tailings in porous
bricks with low thermal conductivity,” Construction
and Building Materials, pp. 43–50.
[25] Kumar, R., Das, P., Beulah, M., Arjun, H.R. (2020)
“Geopolymer Bricks Using Iron Ore Tailings, Slag
Sand, Ground Granular Blast Furnace Slag and Fly
Ash. in: Alshaaer, M., Jeon, H. Y. (Eds.), Geopolymers
and Other Geosynthetics. IntechOpen, London. DOI:
10.5772/intechopen.81748
[26] Beulah, M., Sudhir, M. R., Mohan, M. K., Gayathri,
G., Jain, D. (2021) “Mine Waste-Based Next
Generation Bricks: A Case Study of Iron Ore Tailings,
Red Mudand GGBS Utilization in Bricks,” Advances
in Materials Science and Engineering, pp. 1–10.
[27] Zhang, N., Tang, B., Liu, X. (2021) “Cementitious
activity of iron ore tailing and its utilization in
cementitious materials, bricks and concrete,”
Construction and Building Materials, 288, 123022,
doi.org/10.1016/j.conbuildmat.2021.123022
[28] Thejas, H.K. Hossiney, N. (2022) “A short review
on environmental impacts and application of iron ore
tailings in development of sustainable eco-friendly
bricks,” Materialstoday Proceedings, pp. 327–331.
[29] Thejas H.K., Hossiney, N. (2022) “Alkali-activated
bricks made with mining waste iron ore tailings,”
Case Studies in Construction Materials, 16, e00973.
doi.org/10.1016/j.cscm.2022.e00973
[30] Thejas H.K., Hossiney, N. (2022) “Compressed
unfired blocks made with iron ore tailings and
slag,” Cogent Engineering, 9 (1), 2032975. DOI:
10.1080/23311916.2022.2032975
[31] Xiaolong, Z., Shiyu, Z., Hui, L., Yingliang, Z. (2021)
“Disposal of mine tailings via geopolymerization,”
Journal of Cleaner Production, pp. 1–15.
[32] He, X., Yuhua, Z., Qaidi, S., Isleem, H. F., Zaid, O.,
Althoey, F., Ahmad, J. (2022) “Mine tailings-based
geopolymers: A comprehensive review,” Ceramics
International, pp. 24192–24212.
[33] Krishna, R.S., Shaikh, F., Mishra, J., Lazorenko,
G., Kasprzhitskii, A. (2021) “Mine tailings-based
geopolymers: Properties, applications and industrial
prospects,” Ceramics International, pp. 17826–17843.
[34] Rao, F., Liu, Q. (2015) “Geopolymerization and Its
Potential Application in Mine Tailings Consolidation:
A Review,” Mineral Processing and Extractive
Metallurgy Review, pp. 399–409.
[35] Cook, E.M., DuMont, D. (1991) Process Drying
Practice, McGraw-Hill, New York.
[36] Nakhaei, F., Irannajad, M. (2017) “Sulphur removal
of iron ore tailings by flotation,” Journal of Dispersion
Science and Technology, pp. 1755–1763.
[37] Zanko, L. M., Niles, H. B., Oreskovich, J. A. (2008)
“Mineralogical and microscopic evaluation of coarse
taconite tailings from Minnesota taconite operations,”
Regulatory Toxicology and Pharmacology, pp. S51-S65.
[38] Hidalgo, A., Andrade, C., Alonso, C. (2001) “An
accelerated Leaching Test to Evaluate the Long-Term
Behaviour of Concrete in Waste Disposal,” L’Industria
Italiana del Cemento, pp. 498–507.
[39] Skousen, J., Simmons, J., McDonald, L.M.,
Ziemkiewicz, P. (2002) “Acid-base accounting to
V. (2022) “Mine waste as a sustainable resource for
facing bricks,” Journal of Cleaner Production, 368,
133118. doi.org/10.1016/j.jclepro.2022.133118
[17] Ahmari, S., Zhang, L. (2012) “Production of eco-
friendly bricks from copper mine tailing through geo-
polimerization,” Construction and Building Materials,
pp. 323–331,
[18] Gitari, M. W., Akinyemi, S.A., Thobakgale, R.,
Ngoejana, P.C., Ramugondo, L., Matidza, M.,
Mhlongo, S.E., Dacosta, F.A., Nemapate, N. (2018)
“Physicochemical and Mineralogical Characterization
of Musina Mine Copper and New Union Gold Mine
Tailings: Implications for Fabrication of Beneficial
Geopolymeric Construction Materials,” Journal of
African Earth Sciences, pp. 218–228.
[19] Roy, S., Adhikari, G. R. (2007) “Use of gold mill
tailings in making bricks: A feasibility study,” Waste
Management &Research, pp. 475–482.
[20] Valdez, J., Aguilar, J., Sanchez, L. (2020) “Diseño
e implementación de un proceso alternativo para la
fabricación de ladrillos a partir de relaves mineros de
Oro,” Ingeniare. Rev. Chil. Ing., pp. 268–276.
[21] Benahsina, A., Taha, Y., Bouachera, R., Elomari,
M., Bennouna, M.A. (2021) “Manufacture and
Characterization of Fired Bricks from Gold Mine
Waste Rocks,” Minerals, 11, 695. doi.org/10.3390
/min11070695
[22] Wei, Z., Zhao, J., Wang, W., Yang, Y., Zhuang, S.,
Lu, T., Hou, Z. (2021) “Utilizing gold mine tail-
ings to produce sintered bricks,” Construction and
Building Materials. 282, 122655. doi.org/10.1016
/j.conbuildmat.2021.122655
[23] Kuranchie, F. A., Shukla, S. K., Habibi, D. (2016)
“Utilisation of iron ore mine tailings for the produc-
tion of geopolymer bricks,” International Journal of
Mining, Reclamation and Environment, pp. 1–24.
[24] Li, R., Zhou, Y., Li, C., Li, S., Huang, Z. (2019)
“Recycling of industrial waste iron tailings in porous
bricks with low thermal conductivity,” Construction
and Building Materials, pp. 43–50.
[25] Kumar, R., Das, P., Beulah, M., Arjun, H.R. (2020)
“Geopolymer Bricks Using Iron Ore Tailings, Slag
Sand, Ground Granular Blast Furnace Slag and Fly
Ash. in: Alshaaer, M., Jeon, H. Y. (Eds.), Geopolymers
and Other Geosynthetics. IntechOpen, London. DOI:
10.5772/intechopen.81748
[26] Beulah, M., Sudhir, M. R., Mohan, M. K., Gayathri,
G., Jain, D. (2021) “Mine Waste-Based Next
Generation Bricks: A Case Study of Iron Ore Tailings,
Red Mudand GGBS Utilization in Bricks,” Advances
in Materials Science and Engineering, pp. 1–10.
[27] Zhang, N., Tang, B., Liu, X. (2021) “Cementitious
activity of iron ore tailing and its utilization in
cementitious materials, bricks and concrete,”
Construction and Building Materials, 288, 123022,
doi.org/10.1016/j.conbuildmat.2021.123022
[28] Thejas, H.K. Hossiney, N. (2022) “A short review
on environmental impacts and application of iron ore
tailings in development of sustainable eco-friendly
bricks,” Materialstoday Proceedings, pp. 327–331.
[29] Thejas H.K., Hossiney, N. (2022) “Alkali-activated
bricks made with mining waste iron ore tailings,”
Case Studies in Construction Materials, 16, e00973.
doi.org/10.1016/j.cscm.2022.e00973
[30] Thejas H.K., Hossiney, N. (2022) “Compressed
unfired blocks made with iron ore tailings and
slag,” Cogent Engineering, 9 (1), 2032975. DOI:
10.1080/23311916.2022.2032975
[31] Xiaolong, Z., Shiyu, Z., Hui, L., Yingliang, Z. (2021)
“Disposal of mine tailings via geopolymerization,”
Journal of Cleaner Production, pp. 1–15.
[32] He, X., Yuhua, Z., Qaidi, S., Isleem, H. F., Zaid, O.,
Althoey, F., Ahmad, J. (2022) “Mine tailings-based
geopolymers: A comprehensive review,” Ceramics
International, pp. 24192–24212.
[33] Krishna, R.S., Shaikh, F., Mishra, J., Lazorenko,
G., Kasprzhitskii, A. (2021) “Mine tailings-based
geopolymers: Properties, applications and industrial
prospects,” Ceramics International, pp. 17826–17843.
[34] Rao, F., Liu, Q. (2015) “Geopolymerization and Its
Potential Application in Mine Tailings Consolidation:
A Review,” Mineral Processing and Extractive
Metallurgy Review, pp. 399–409.
[35] Cook, E.M., DuMont, D. (1991) Process Drying
Practice, McGraw-Hill, New York.
[36] Nakhaei, F., Irannajad, M. (2017) “Sulphur removal
of iron ore tailings by flotation,” Journal of Dispersion
Science and Technology, pp. 1755–1763.
[37] Zanko, L. M., Niles, H. B., Oreskovich, J. A. (2008)
“Mineralogical and microscopic evaluation of coarse
taconite tailings from Minnesota taconite operations,”
Regulatory Toxicology and Pharmacology, pp. S51-S65.
[38] Hidalgo, A., Andrade, C., Alonso, C. (2001) “An
accelerated Leaching Test to Evaluate the Long-Term
Behaviour of Concrete in Waste Disposal,” L’Industria
Italiana del Cemento, pp. 498–507.
[39] Skousen, J., Simmons, J., McDonald, L.M.,
Ziemkiewicz, P. (2002) “Acid-base accounting to