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Gouda, A., elsheikh, R., Elbshary, R., Atia, B., Gado, M. (2024). Review on Tungsten Recovery and Sustainable Practices. Bulletin of Faculty of Science, Zagazig University, 2024(2), 142-154. doi: 10.21608/bfszu.2023.245228.1334
Ayman A Gouda; Ragaa elsheikh; Rawan Elbshary; Bahig Atia; Mohamed A Gado. "Review on Tungsten Recovery and Sustainable Practices". Bulletin of Faculty of Science, Zagazig University, 2024, 2, 2024, 142-154. doi: 10.21608/bfszu.2023.245228.1334
Gouda, A., elsheikh, R., Elbshary, R., Atia, B., Gado, M. (2024). 'Review on Tungsten Recovery and Sustainable Practices', Bulletin of Faculty of Science, Zagazig University, 2024(2), pp. 142-154. doi: 10.21608/bfszu.2023.245228.1334
Gouda, A., elsheikh, R., Elbshary, R., Atia, B., Gado, M. Review on Tungsten Recovery and Sustainable Practices. Bulletin of Faculty of Science, Zagazig University, 2024; 2024(2): 142-154. doi: 10.21608/bfszu.2023.245228.1334

Review on Tungsten Recovery and Sustainable Practices

Article 15, Volume 2024, Issue 2, July 2024, Page 142-154  XML PDF (1.02 MB)
Document Type: Original Article
DOI: 10.21608/bfszu.2023.245228.1334
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Authors
Ayman A Gouda email 1; Ragaa elsheikh2; Rawan Elbshary3; Bahig Atia4; Mohamed A Gado4
1Chemistry Department, Faculty of Science, Zagazig University, Zagazig, Egypt
2Chemistry Department, Faculty of Science, Zagazig University, Zagazig, 44519, Egypt.
3Chemistry Department, Faculty of Science, Zagazig University, Zagazig, 44519, Egypt
4Nuclear Materials Authority, El Maadi, Cairo P.O. Box 530, Egypt.
Abstract
Tungsten, a versatile transition metal located in Group VI of the Periodic Table, is prized for its strength and eco-friendly attributes, finding essential roles in numerous industries. Its applications range from light bulb filaments and X-ray tubes to military technology, thanks to its outstanding hardness and density. In the chemical sector, tungsten compounds act as catalysts, sourced from minerals like wolframite and scheelite via flotation methods. Tungsten's unique capability to form diverse complexes in different oxidation states is notable, with primary minerals being wolframite and scheelite and secondary ones influenced by geological processes. Recovery of tungsten has advanced from historical empirical methods to more efficient and eco-conscious practices involving digestion with soda or caustic soda, crystallisation, and the use of solvent extraction or ion exchange to eliminate impurities. Commercial APT production employs an evaporation crystallization process and pyrometallurgical methods, such as roasting, carbothermic reduction, and electric arc melting, to reduce tungsten oxide to its metal form. These processes, combined with novel approaches and recycling methods, contribute to the versatile and sustainable use of this valuable metal. The provided information summarises the recovery of tungsten from complex sources, including the removal of arsenic from tungsten residues. Key points encompass tungsten recovery methods, hydrometallurgy for tungsten recovery, arsenic removal from tungsten residues, and innovative processes and recycling.
Keywords
Review; Tungsten; Recovery; Sustainable Practices
Main Subjects
Basic and applied research of Chemistry,
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