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Accumulation of low-grade iron ore tailings (IOTs) generated during the processing of high-grade iron ore has become a great threat to environment. Although wide range of research works has carried out to recover the iron values from the IOTs, but the solid recovery value has limited to ca. 50% in Indian context. In order to attain a maximum iron recovery and to utilize these solid wastes for future needs, an attention has shed on the topics of hydrometallurgy and applied nanomaterial synthesis from IOTs. Iron containing nanoparticles (ICNs) have huge potential in environmental and energy related applications. A wide range of synthesis methods has developed to produce ICNs from the mine waste. It is evident from the recent research works that converting waste materials into value added products are gaining more attentions. Objective of this review is to analyse the green synthesis routes to prepare ICNs from mine waste, starting from the physio chemical identification of waste material followed by discussion on various methods of ICNs synthesis routes from mine waste. It includes selective leaching method. Finally, the use of ICNs for environmental application had discussed in brief.
Wydawca
Czasopismo
Rocznik
Tom
Strony
78--85
Opis fizyczny
Bibliogr. 28 poz., tab.
Twórcy
autor
- Indian Institute of Engineering Science and Technology, Shibpur, West Bengal, India
autor
- Indian Institute of Engineering Science and Technology, Shibpur, West Bengal, India
Bibliografia
- 1. Ambikadevi, V. and M. Lalithambika (2000). "Effect of organic acids on ferric iron removal from iron-stained kaolinite." Applied Clay Science 16(3-4): 133-145.
- 2. Association, W.S. (2014). "World steel in figures 2014." World Steel Association: Brussels, Belgium.
- 3. Cornell, R.M. and U. Schwertmann (2003). The iron oxides: structure, properties, reactions, occurrences and uses, John Wiley & Sons.
- 4. Darezereshki, E., A. Khodadadi Darban and M. Abdollahy (2018). "Synthesis of magnetite nanoparticles from iron ore tailings using a novel reduction-precipitation method." Journal of Alloys and Compounds 749: 336-343.
- 5. Das, B., S. Prakash, B. Mohapatra, S. Bhaumik and K. Narasimhan (1992). "Beneficiation of iron ore slimes using hydrocyclone." Mining, Metallurgy & Exploration 9(2): 101-103.
- 6. Fiscor, S. (2019). "Dam Failure Pushes Iron Ore Prices Higher." Precious Metals.
- 7. Ghose, M. and P. Sen (2001). "Assessment of effective design of tailing pond for safe disposal of iron ore tailings."
- 8. Giri, S., N. Das and G. Pradhan (2011). "Synthesis and characterization of magnetite nanoparticles using waste iron ore tailings for adsorptive removal of dyes from aqueous solution." Colloids and Surfaces A: Physicochemical and Engineering Aspects 389(1-3): 43-49.
- 9. Gray, M.A. (1990). "The United Nations Environment Programme: An Assessment." Envtl. L. 20: 291.
- 10. Havlík, T. (2014). Hydrometallurgy: Principles and applications, Elsevier.
- 11. Kumar, R., R. Sakthivel, R. Behura, B. Mishra and D. Das (2015). "Synthesis of magnetite nanoparticles from mineral waste." Journal of Alloys and Compounds 645: 398-404.
- 12. Li, C., H. Sun, J. Bai and L. Li (2010). "Innovative methodology for comprehensive utilization of iron ore tailings: Part 1. The recovery of iron from iron ore tailings using magnetic separation after magnetizing roasting." Journal of Hazardous Materials 174(1-3): 71-77.
- 13. Müller, D.B., T. Wang, B. Duval and T.E. Graedel (2006). "Exploring the engine of anthropogenic iron cycles." Proceedings of the National Academy of Sciences 103(44): 16111-16116.
- 14. Muthukannan, V., K. Praveen and B. Natesan (2015). "Fabrication and characterization of magnetite/reduced graphene oxide composite incurred from iron ore tailings for high performance application." Materials Chemistry and Physics 162: 400-407.
- 15. Parida, K. and N. Das (1996). "Reductive dissolution of hematite in hydrochloric acid medium by some inorganic and organic reductants: A comparative study."
- 16. Petcharoen, K. and A. Sirivat (2012). "Synthesis and characterization of magnetite nanoparticles via the chemical co-precipitation method." Materials Science and Engineering: B 177(5): 421-427.
- 17. Porsani, J.L., F.A.N. d. Jesus and M.C. Stangari (2019). "GPR Survey on an Iron Mining Area after the Collapse of the Tailings Dam I at the Córrego do Feijão Mine in Brumadinho-MG, Brazil." Remote Sensing 11(7): 860.
- 18. Pradip (2006). "Processing of alumina-rich Indian iron ore slimes." Transactions of the Indian Institute of Metals 59(5): 551-568.
- 19. Priyadarshana, G., N. Kottegoda, A. Senaratne, A. d. Alwis and V. Karunaratne (2015). "Synthesis of magnetite nanoparticles by top-down approach from a high purity ore." Journal of Nanomaterials 16(1): 317.
- 20. Rao, G., R. Markandeya and S. Sharma (2016). "Recovery of Iron Values from Iron Ore Slimes of Donimalai Tailing Dam." Transactions of the Indian Institute of Metals 69(1): 143-150.
- 21. Rauf, M., M. Meetani and S. Hisaindee (2011). "An overview on the photocatalytic degradation of azo dyes in the presence of TiO2 doped with selective transition metals." Desalination 276(1-3): 13-27.
- 22. Roy, S. and A. Das (2008). "Characterization and processing of low-grade iron ore slime from the Jilling area of India." Mineral Processing & Extractive Metallurgy Review 29(3): 213-231.
- 23. Roy, S., A. Das and M. Mohanty (2007). "Feasibility of producing pellet grade concentrate by beneficiation of iron ore slime in India." Separation Science and Technology 42(14): 3271-3287.
- 24. Rudramuniyappa, M. (1997). "Iron ore fines and their impact on environment in Sandur-Hospet region, Bellary district, Karnataka, India."
- 25. Sidhu, P., R. Gilkes, R. Cornell, A. Posner and J. Quirk (1981). "Dissolution of iron oxides and oxyhydroxides in hydrochloric and perchloric acids." Clays and Clay Minerals 29(4): 269-276.
- 26. Thella, J.S., A.K. Mukherjee and N.G. Srikakulapu (2012). "Processing of high alumina iron ore slimes using classification and flotation." Powder Technology 217: 418-426.
- 27. Yan, W., H.-L. Lien, B.E. Koel and W.-x. Zhang (2013). "Iron nanoparticles for environmental clean-up: recent developments and future outlook." Environmental Science: Processes & Impacts 15(1): 63-77.
- 28. Yellishetty, M., P. Ranjith and A. Tharumarajah (2010). "Iron ore and steel production trends and material flows in the world: Is this really sustainable?" Resources, conservation and recycling 54(12): 1084-1094.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-ecfb49ee-8d8c-49b1-83ec-2eea808db6b3