GLOBAL DEMAND, APPLICATION, PRODUCTION SCALE OF LITHIUM COMPOUNDS

Murodjon Samadiy; Shafoat Namazov; Dilbar Ramazonova; Sitora Kayumova

doi:10.5281/zenodo.8101624

GLOBAL DEMAND, APPLICATION, PRODUCTION SCALE OF LITHIUM COMPOUNDS

30.06.2023 International Scientific Journal "Science and Innovation". Series A. Volume 2 Issue 6

Murodjon Samadiy, Shafoat Namazov, Dilbar Ramazonova, Sitora Kayumova

Abstract. Demand for lithium is growing rapidly as its use increases in a variety of applications such as rechargeable batteries, light aircraft alloys and fusion. Demand for lithium is expected to triple by 2025 at the expense of batteries, especially those used in electric vehicles. To meet the growing consumption of lithium, it is necessary to increase the production of lithium from various resources. The reserves of lithium resources in salt water of salt lakes, sea and geothermal water are 70-80% of the total, which are excellent raw materials for lithium extraction. Compared with minerals, the recovery of lithium from water resources is promising because this water recovery of lithium is more common, more environmentally friendly, and cost effective. There are many ways to extract lithium from water resources. Among the existing methods, the adsorption method is more promising in terms of production method. Therefore, important advances in the field of ion-exchange-adsorption methods for extracting lithium from water resources have been studied in detail.

Keywords: lithium recovery, saline likes, adsorption, lithium-ion sieves

References:

1. Murodjon Samadiy and Tianlong Deng. Lithium Recovery from Water Resources by Ion Exchange and Sorption Method. Journal of the Chemical Society of Pakistan. J.Chem.Soc.Pak., Vol. 43, No. 04, 2021 P. 406-416. 2. Bakhodir Abdullayev, Ilkham Usmanov, Murodjon Samadiy, Tianlong Deng. Lithium Recovery from Water Resources by Membrane and Adsorption Methods. International Journal of Engineering Trends and Technology. 2022, 70(9), P. 319-329. 3. Kesler SE, Gruber PW, Medina PA, Keoleian GA, Everson MP, Wallington TJ Global lithium resources: relative importance of pegmatite, brine and other deposits. Ore geol. 2012. Rev. 48, P. 55-69. 4. Glasstone S., Senonske A. Nuclear Reactor Engineering, 3rd Ed., CBS Publisher & Distributor, Delhi, India, 1986. 5. Tsuchiya K., Kawamura H. Fabrication and Characterizationn of 6Li-enriched Li2TiO3 Pebbles for a High Li-burnup Irradiation Tests, Japan Atomic Energy Agency, 2006. 6. Opitz A., Badami P., Shen L., Vignarooban K., Kannan. Can Li-Ion batteries be the panacea for automotive applications? Renew. Sust. Energ. 2017. Rev. 68, P. 685-692. 7. Evans RK Lithium's future supply, demand. North. miner. 2010. 96 (35), P. 11-12. 8. Winter M., Brodd R.J. What are batteries, fuel cells, and supercapacitors? Chem. Rev. 2004. 104 (10), P. 4245-4269. 9. Bruce P.G, Freunberger S.A., Hardwick L.J., Tarascon J.M. Li-O2 and Li-S batteries with high energy storage. Nat. mater. 2012. 11 (1), P. 19-29. 10. Hykawy J. Looking at lithium: discussing market demand for lithium in electronics. mater. World Ceram. Lithium 2010. 18 (5), P. 34-35. 11. Siame E., Pascoe D. Extraction of lithium from micaceous waste from China clay production. miner. Eng. 2011. 24 (14), P. 1595-1602. doi:10.1016/j.min.eng.2011.8.013. 12. Yaksic A., Tilton JE Using the cumulative availability curve to assess the threat of mineral depletion: the case of lithium. resource. Policy 2009. 34, P. 185-194. 13. Evans J.K. An abundance of lithium. Accessed on 27 November 2011. 14. A.S. Brouwer, M. van den Broek, W. Zappa, W. C. Turkenburg, A. Faaij. 2016. Least-cost options for integrating intermittent renewables in low-carbon power systems. Appl. Energy 161, P. 48-74. 15. Pellow MA, Emmott CJM, Barnhart CJ, Benson SM Hydrogen or batteries for grid storage? A net energy analysis. Energy Environment. sci. 2015.8(7), P. 1938-1952. 16. Liu Q., Ai H. & Li Z. Potassium sorbate as an efficient and green catalyst for knoevenagel condensation.Ultrasonics Sonochemistry, (2011). 18(2) P. 477–479. 17. Ji Z.-Y., Yang F.-J., Zhao Y.-Y., Liu J., Wang N. & Yuan J.-S. Preparation of titanium-base lithium ionic sieve with sodium persulfate as eluent and itsperformance.Chemical Engineering Journal, (2017). 328, P.768–775. 18. Chitrakar R., Makita Y., Ooi K., & Sonoda A. Synthesis of iron-doped manganese oxides with an ion-sieve property: Lithium adsorption from Bolivianbrine. Industrial & Engineering Chemistry Research, (2014c). 53(9), P. 3682–3688. 19. Rjabtsev A.D., Kotsupalo N.P., Kishkan L.N. Method of Producing Lithium Hydroxide from Brines and Plant for Method Embodiment. 2003. 20. Chitrakar R., Kanoh H., Miyai Y., Ooi K. Recovery of lithium from seawater using manganese oxide adsorbent (H1.6Mn1.6O4) derived from Li1.6Mn1.6O4. Ind. Eng. Chem. Res. 2001. 40(9), P. 2054–2058 21. Chitrakar R., Makita Y., Ooi K., Sonoda A. Lithium recovery from salt-like brine by H2TiO3. Dalton T. 2014. 43 (23), P. 8933–8939. 22. Zhou ZY, Qin W., Fei WY Extraction equilibria of lithium with tributyl phosphate in three diluents. J. Chem. Eng. Data 2011a. 56 (9), P. 3518-3522.