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O‘zbekiston respublikasi oliy ta’lim fan va innovatsiyalar vazirligi
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| bet | 3/3 | | Sana | 14.02.2024 | | Hajmi | 484,79 Kb. | | #156393 |
Bog'liq Adabiyotlar sharhi Rashidov Davron Инструкции по дайректам в КЗ (1), 1-mavzu. “Innovatsion iqtisodiyot” faniga kirish Reja, Information, Шаблон Объяснительного (2), Текст английский песни, алгебра 1666, Театр, ish xaqi tolash banklarda, Metall konstruksiyalari Q. Saydullayev 2010 , 2 5386797705479590594 — копия, Документ Microsoft Word, Monthly report, 100 plotnost 4 ta 08.05.2023, ARAMV102 N1 P32 43Adabiyotlar ro’yxati
1. U.S. Geological Survey. Mineral сommodity summaries. February 2014. 196 р. Рр. 176-177.
2. Brent Nykoliation. Corporate Development at Energizer Resources Inc. Lenbrook Canada, 2013. URL: http://energizerresources.com/vanadium/vanadium-and-steel.html (Sunday December 02, 2012).
3. Gan Yong., Dong Han. Review of applications of vanadium in steels // Proceedings of International seminar on production and application of high strength seismic grade rebar containing vanadium. China Iron & Steel Research Institute Group, 2010. Pp. 6-8.
4. Борисенко Л.Ф., Слотвинский-Сидак Н.П., Поликашина Н.С. Минеральное сырье. Ванадий // Справочник. М.: ЗАО «Геоинформмарк», 1998. 33 с.
5. Коршунов Б.Г. Ванадий // Химическая энциклопедия: В 5 т. Т. 1. М.: Изд-во «Советская энциклопедия», 1988. С. 672–675.
6. Музгин В.Н., Хамзина Л.Б., Золотавин В.Л., Безруков И.Я. Аналитическая химия ванадия. М.: Наука, 1981. 216 с.
7. Zaw K., Sutherland L., Yui T-F. at all. LA-ICP-MS Trace Element and Oxygen Isotope Variation of Vanadium-Rich Ruby and Sapphire within Mogok Gemfield, Myanmar. Goldschmidt 2013 Conference Abstracts // Mineralogical Magazine. 2013. 77(5). P-2582.
8. Беспамятнов Г.П., Кротов Ю.А. Предельно допустимые концентрации химических веществ в окружающей среде. Справочник. Л.: Химия, 1985. 528с.
9. Мур Дж.В., Рамамурти С. Тяжелые металлы в природных водах. М.: Мир, 1987. 288с.
10. Prange A., Kremling K. Distribution of Dissolved Molybdenum, Uranium and Vanadium in Baltic Sea Waters // Mar. Chem. 1985. V. 16. Pp. 259-274.
11. Costigan M., Cary R., Dobson S. Vanadium pentoxide and other inorganic vanadium compounds // Concise International Chemical Assessment Documents
114.
12. Иванов В.В. Ванадий. Экологическая геохимия элементов. Кн. 4. М.: Недра, 1996. С. 62-91.
13.Мизин В.Г., Рабинович Е.М., Сирина Т.П., Добош В.Г. и др. Комплексная переработка ванадиевого сырья: химия и технология. Екатеринбург: УрО РАН, 2005. 416 с.
14. Подземное выщелачивание полиэлементных руд / Н.П. Лаверов, И.Г. Абдульманов, К.Г. Бровин и др.; Под ред. Н.П. Лаверова. М.: Издательство Академии горных наук, 1998. 446 с.
15. Ванадий и его соединения (67). Серия «Научные обзоры советской литературы по токсичности и опасности химических веществ». М.: Центр международных проектов ГКНТ, 1984.
16. Вредные химические вещества. Неорганические соединения V-VIII групп: Справ. изд. / Под ред. В.А. Филова и др. Л.: Химия, 1989. 592с.
17. Санитарно-эпидемиологические правила и нормативы СанПиН
2.1.4.2580-10 : утв. М-вом юстиции РФ 01.05.2010. М., 2010.
18. Bureau of Indian Standards, Discharge Limits of the
Effluents. IS 2490: 1981, New Delhi, 1981.
19. Kosandrovich E.G., Soldatov V.S. Fibrous Ion Exchangers // Ion Exchange Technology I: Theory and Materials. Chapter 9. Inamuddin and M. Luqman (eds.). Springer Science+Business Media B.V. 2012. Pp. 299–371.
20. Редкие и рассеянные элементы. Химия и технология. В 3-х книгах. Книга II: Учебник для вузов / Коровин С.С., Дробот Д.В., Федоров П.И./ Под ред. С.С. Коровина. М.: МИСИС, 1999. 464 с.
21. Bailor J.C. Comprehensive inorganic chemistry. Oxford: Pergamon Press. 1973. V. 3. Pp. 519-521.
22.. Romanovskaia, E., Romanovski, V., Kwapinski, W., & Kurilo, I. Selective recovery of vanadium pentoxide from spent catalysts of sulfuric acid production: Sustainable approach // Hydrometallurgy. 2021. (200). C. 105568.
23. Wu, L., Dai, C., Wang, H., Wang, J., & Dong, Y. (2021).Leaching of vanadium, potassium, and iron from spent catalyst of the manufacture of sulfuric acid // Journal of Materials Research and Technology. 2021. (11). C. 905–913.
24. Wang, S., Xie, Y., Yan, W., Wu, X., Wang, C. T., & Zhao, F.Leaching of vanadium from waste V2O5-WO3/TiO2 catalyst catalyzed by functional microorganisms // Science of The Total Environment. 2018. (639). C. 497–503.
25. Mohanty, C., Behera, S. S., Marandi, B., Tripathy, S. K., Parhi, P. K., & Sanjay, K. (2021). Citric acid mediated leaching kinetics study and comprehensive investigation on extraction of vanadium (V) from the spent catalyst. Separation and Purification Technology, 276, 119377.
26. Ognyanova, A., Ozturk, A. T., De Michelis, I., Ferella, F., Taglieri, G., Akcil, A., & Vegliò, F. Metal extraction from spent sulfuric acid catalyst through alkaline and acidic leaching // Hydrometallurgy. 2009. № 1–2 (100). C. 20–28.
27. Nikiforova A., Kozhura O., Pasenko O. Leaching of vanadium by sulfur dioxide from spent catalysts for sulfuric acid production // Hydrometallurgy. 2016. (164). C. 31–37.
28. Nguyen T. H., Lee M. S. Recovery of molybdenum and vanadium with high purity from sulfuric acid leach solution of spent hydrodesulfurization catalysts by ion exchange // Hydrometallurgy. 2014. (147–148). C. 142–147.
29. Mishra, D., Kim, D. J., Ralph, D. E., Ahn, J. G., & Rhee, Y. H.Bioleaching of vanadium rich spent refinery catalysts using sulfur oxidizing lithotrophs // Hydrometallurgy. 2007. № 1–4 (88). C. 202–209.
30. Mazurek K., Białowicz K., Trypuć M. Recovery of vanadium, potassium and iron from a spent catalyst using urea solution // Hydrometallurgy. 2010. № 1–4 (103). C. 19–24.
31. Lozano L. J., Juan D. Leaching of vanadium from spent sulphuric acid catalysts // Minerals Engineering. 2001. № 5 (14). C. 543–546.
32. Lee, D., Joo, S. H., Shin, D. J., & Shin, S. MRecovery of vanadium and cesium from spent sulfuric acid catalysts by a hydrometallurgical process // Green Chemistry. 2022. № 2 (24). C. 790–799.
33. Teng Q., Yang Z., Wang H. Recovery of vanadium and nickel from spent-residue oil hydrotreating catalyst by direct acid leaching-solvent extraction // Transactions of Nonferrous Metals Society of China. 2023. № 1 (33). C. 325–336.
34. Wen, J., Hou, X., Yao, M., Chen, J. A., Tian, M., Feng, E., ... & Xu, S.Tuning of vanadium valence for value-added recycling and utilization of vanadium from spent Selective Catalytic Reduction Catalysts // Journal of Cleaner Production. 2023. (390). C. 136151.
35. Zhang, D., Liu, Y., Hu, Q., Ke, X., Yuan, S., Liu, S., ... & Hu, J. Sustainable recovery of nickel, molybdenum, and vanadium from spent hydroprocessing catalysts by an integrated selective route // Journal of Cleaner Production. 2020. (252). C. 119763.
36. Li, W., Yan, X., Niu, Z., & Zhu, X. Selective recovery of vanadium from red mud by leaching with using oxalic acid and sodium sulfite // Journal of Environmental Chemical Engineering. 2021. № 4 (9). C. 105669.
37. Wu, W., Wang, C., Bao, W., & Li, H. Selective reduction leaching of vanadium and iron by oxalic acid from spent V 2 O 5 -WO 3 /TiO 2 catalyst // Hydrometallurgy. 2018. (179). C. 52–59.
38. Sahu, K. K., Agrawal, A., & Mishra, D. Hazardous waste to materials:
Recovery of molybdenum and vanadium from acidic leach liquor of spent
hydroprocessing catalyst using alamine 308. Journal of environmental
management, (2013) 125, 68-73.
39. Chen, X. Y., Lan, X. Z., Zhang, Q. L., & Jun, Z. H. O. U. (2010). Leaching vanadium by high concentration sulfuric acid from stone coal. Transactions of Nonferrous Metals Society of China, 20, s123-s126.
40. Aarabi-Karasgani, M., Rashchi, F., Mostoufi, N., & Vahidi, E. (2010). Leaching of vanadium from LD converter slag using sulfuric acid. Hydrometallurgy, 102(1-4), 14-21.
41. Mahandra, H., Singh, R., & Gupta, B. (2020). Recovery of vanadium (V) from synthetic and real leach solutions of spent catalyst by solvent extraction using Cyphos IL 104. Hydrometallurgy, 196, 105405.
42. Chen, L., Wang, Z., Qin, Z., Zhang, G., Yue, H., Liang, B., & Luo, D. (2021). Dissolution behavior and mechanism of low valence vanadium of vanadium-iron spinel in sulfuric acid solution. Journal of Materials Research and Technology, 12, 1391-1402.
43 . Wen, J., Hou, X., Yao, M., Chen, J. A., Tian, M., Feng, E., ... & Xu, S. (2023). Tuning of vanadium valence for value-added recycling and utilization of vanadium from spent Selective Catalytic Reduction Catalysts. Journal of Cleaner Production, 390, 136151.
44. Li, H., Feng, Y., Wang, H., Li, H., & Wu, H. (2020). Separation of V (V) and Mo (VI) in roasting-water leaching solution of spent hydrodesulfurization catalyst by co-extraction using P507-N235 extractant. Separation and Purification Technology, 248, 117135.
45. Lee, D., Joo, S. H., Shin, D. J., & Shin, S. M. (2022). Recovery of vanadium and cesium from spent sulfuric acid catalysts by a hydrometallurgical process. Green Chemistry, 24(2), 790-799.
46. Choi, I. H., Moon, G., Lee, J. Y., & Jyothi, R. K. (2018). Extraction of tungsten and vanadium from spent selective catalytic reduction catalyst for stationary application by pressure leaching process. Journal of Cleaner Production, 197, 163-169.
47. Liu, Q., Quan, S., Liu, Z., & Liu, Q. (2022). Leaching of vanadium and tungsten from spent V2O5-WO3/TiO2 catalyst by ionic liquids. Hydrometallurgy, 213, 105938.
48. Tran, T. T., Liu, Y., & Lee, M. S. (2021). Recovery of pure molybdenum and vanadium compounds from spent petroleum catalysts by treatment with ionic liquid solution in the presence of oxidizing agent. Separation and Purification Technology, 255, 117734.
49. Wang, B., & Yang, Q. (2022). Recovery of V2O5 from spent SCR catalyst by H2SO4-ascorbic acid leaching and chemical precipitation. Journal of Environmental Chemical Engineering, 10(6), 108719.
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