RESEARCH JOURNAL OF PURE SCIENCE AND TECHNOLOGY (RJPST )
E-ISSN 2579-0536
P-ISSN 2695-2696
VOL. 7 NO. 6 2024
DOI: 10.56201/rjpst.v7.no6.2024.pg67.81
Ayodeji K. Ogundana
Integration of mineral waste into other applications such as concrete production is a win-win situation for the effective management of mining and mineral wastes. Search for an effective method of waste valorization a by-product for an industrial application is highly significant to the circular economy. Thus, this work carefully reviewed the various useful mineral wastes and their processing method as alternative aggregate for concrete production. From the study, it was established that a well processed mineral waste will function well in concrete production. Hence reducing the overall dependence on natural aggregates for the building and construction industries as well as reducing the environmental degradation that mining sites are subjected to during the mining activities. The information from this review will help in the promotion of the circular economy.
Mining, minerals, waste, processing, aggregates
[1] Alcalde, J., Kelm, U., & Vergara, D. (2018). Historical assessment of metal recovery
potential from old mine tailings: A study case for porphyry copper tailings, Chile.
Minerals Engineering, 127, 334-338.
[2] Edraki, M., Baumgartl, T., Manlapig, E., Bradshaw, D., Franks, D. M., & Moran, C. J.
(2014). Designing mine tailings for better environmental, social and economic outcomes:
a review of alternative approaches. Journal of Cleaner Production, 84, 411-420.
[3] Cornejo, N., Pascual, L., Tamayo, A., Rubio, F., Rodríguez, M. A., & Rubio, J. (2012).
Crystallization mechanism of glass-ceramics prepared from Ni–Cu–Co mining wastes.
Journal of non-crystalline solids, 358(22), 3028-3035.
[4] Rampacek, C. (1982). An overview of mining and mineral processing waste as a
resource. Resources and Conservation, 9, 75-86.
[5] Rosario-Beltré, A. J., Sánchez-España, J., Rodríguez-Gómez, V., Fernández-Naranjo, F.
J., Bellido-Martín, E., Adánez-Sanjuán, P., &Arranz-González, J. C. (2023). Critical Raw
Materials recovery potential from Spanish mine wastes: A national-scale preliminary
assessment. Journal of Cleaner Production, 137163.
[6] Ulubeyli, G. C., Bilir, T., &Artir, R. (2016). Durability properties of concrete produced
by marble waste as aggregate or mineral additives. Procedia engineering, 161, 543-548.
[7] Baic, I., Koziol, W., &Machniak, L. (2016). Aggregates from mineral wastes. In E3S
Web of Conferences (Vol. 8, p. 01068). EDP Sciences.
[8] Moreno-Maroto, J. M., González-Corrochano, B., Alonso-Azcárate, J., Rodríguez, L., &
Acosta, A. (2017). Manufacturing of lightweight aggregates with carbon fiber and
mineral wastes. Cement and Concrete Composites, 83, 335-348.
[9] Amin, M., Tayeh, B. A., &Agwa, I. S. (2020). Effect of using mineral admixtures and
ceramic wastes as coarse aggregates on properties of ultrahigh-performance concrete.
Journal of Cleaner Production, 273, 123073.
[10] Gayana, B. C., & Ram Chandar, K. (2018). Sustainable use of mine waste and tailings
with suitable admixture as aggregates in concrete pavements-A review.
[11] Soltan, A. M. M., Kahl, W. A., Abd EL-Raoof, F., El-Kaliouby, B. A. H., Serry, M. A.
K., & Abdel-Kader, N. A. (2016). Lightweight aggregates from mixtures of granite
wastes with clay. Journal of Cleaner Production, 117, 139-149.
[12] Jones, L., & Gutiérrez, R. U. (2023). Circular ceramics: Mapping UK mineral waste.
Resources, Conservation and Recycling, 190, 106830.
[13] Li, Z., Chen, J., Lv, Z., Tong, Y., Ran, J., & Qin, C. (2023). Evaluation on direct aqueous
carbonation of industrial/mining solid wastes for CO2 mineralization. Journal of
Industrial and Engineering Chemistry, 122, 359-365.
[14] Benarchid, Y., Taha, Y., Zidol, A., Tagnit-Hamou, A., &Benzaazoua, M. (2023). Low-
sulfide mining waste rock as aggregates for concrete: mechanical properties and
durability assessment. In Managing Mining and Minerals Processing Wastes (pp. 3-18).
Elsevier.
[15] Benarchid, Y., Taha, Y., Zidol, A., Tagnit-Hamou, A., &Benzaazoua, M. (2023). Low-
sulfide mining waste rock as aggregates for concrete: mechanical properties and
durability assessment. In Managing Mining and Minerals Processing Wastes (pp. 3-18).
Elsevier.
[16] Santhosh, K. G., Subhani, S. M., &Bahurudeen, A. (2021). Cleaner production of
concrete by using industrial by-products as fine aggregate: A sustainable solution to
excessive river sand mining. Journal of Building Engineering, 42, 102415.
[17] Capasso, I., Lirer, S., Flora, A., Ferone, C., Cioffi, R., Caputo, D., & Liguori, B. (2019).
Reuse of mining waste as aggregates in fly ash-based geopolymers. Journal of Cleaner
Production, 220, 65-73.
[18] Gautam, P. K., Kalla, P., Nagar, R., Agrawal, R., &Jethoo, A. S. (2018). Laboratory
investigations on hot mix asphalt containing mining waste as aggregates. Construction
and Building Materials, 168, 143-152.
[19] Gonzalez, M., Navarrete, I., Arroyo, P., Azúa, G., Mena, J., & Contreras, M. (2017).
Sustainable decision-making through stochastic simulation: Transporting vs. recycling
aggregates for Portland cement concrete in underground mining projects. Journal of
Cleaner Production, 159, 1-10.
[20] Moreno-Maroto, J. M., González-Corrochano, B., Alonso-Azcárate, J., & García, C. M.
(2019). A study on the valorization of a metallic ore mining tailing and its combination
with polymeric wastes for lightweight aggregates production. Journal of Cleaner
Production, 212, 997-1007.
[21] Ju, J., Feng, Y., Li, H., Xu, C., Xue, Z., & Wang, B. (2023). Extraction of valuable
metals from minerals and industrial solid wastes via the ammonium sulfate roasting
process: A systematic review. Chemical Engineering Journal, 457, 141197.
[22] Whitworth, A. J., Forbes, E., Verster, I., Jokovic, V., Awatey, B., &Parbhakar-Fox, A.
(2022). Review on advances in mineral processing technologies suitable for critical metal
recovery from mining and processing wastes. Cleaner Engineering and Technology,
[23] López-Acevedo, F. J., Escavy, J. I., & Herrero, M. J. (2022). Application of Spatial Data
Mining to national mines inventories for exploration and land planning of high place-
value mineral resources. The case of aggregates in Spain. Resources Policy, 79, 103096.
[24] Adom-Asamoah, M., &Afrifa, R. O. (2011). Investigation on the flexural behaviour of
reinforced concrete beams using phyllite aggregates from mining waste. Materials &
Design, 32(10), 5132-5140.
[25] Ballari, S. O., Raffikbasha, M., Shirgire, A., Thakur, L. S., Thenmozhi, S., & Kumar, B.
S. C. (2023). Replacement of coarse aggregates by industrial slag. Materials Today:
Proceedings.