• Покупка статей
  • Telegram_OreMet
Скрыть
Журналы →  Tsvetnye Metally →  2024 →  №10 →  Назад

HEAVY NON-FERROUS METALS
Название Study of pyrometallurgical operation variants for the technology of producing high-nickel cathode materials of the NMC type for lithium-ion batteries
DOI 10.17580/tsm.2024.10.09
Автор Kosov Ya. I., Bogatyrev D. M., Ivanova E. A., Pakalnis V. V.
Информация об авторе

Gipronickel Institute LLC, St. Petersburg, Russia

Ya. I. Kosov, Senior Researcher, R&D Department, Pyrometallurgy Laboratory, Candidate of Technical Sciences, e-mail: KosovYaI@nornik.ru
D. M. Bogatyrev, Researcher, R&D Department, Pyrometallurgy Laboratory, e-mail: BogatyrevDM@nornik.ru
E. A. Ivanova, 2nd Category Engineer, R&D Department, Pyrometallurgy Laboratory, e-mail: IvanovaElAn@nornik.ru
V. V. Pakalnis, Researcher, R&D Department, Hydrometallurgy Laboratory, e-mail: PakalnisVV@nornik.ru
Реферат

As part of the implementation of investment projects to expand the product line of PJSC MMC Norilsk Nickel, Gipronickel Institute conducted studies on the synthesis of precursors of cathode materials (PCAM) and the production of cathode materials (CAM) for lithium-ion batteries — products with high added value. Based on the results of the analysis of scientific literature, it was noted that the methods of high-temperature lithiating roasting are characte rized by diversity. In this regard, the article presents the results of exploratory laboratory studies on the production of active cathode materials (CAM) based on layered lithium-nickel-cobalt-manganese oxide by high-temperature treatment of precursor compounds (PCAM) with a lithium source using single-stage and twostage technologies. A comparison of the electrochemical characteristics of the cathode materials obtained using different technologies was carried out, their chemical and phase compositions, granulometric characteristics, as well as the morphology of the particle surface were studied. When analyzing the cathode materials using the X-ray phase analysis method, it was found that when hightemperature lithiating roasting is carried out using a single-stage technology, the intensity ratio I003/I104 is higher than when the process is carried out in two stages, which indicates reduced cationic mixing between lithium and nickel ions. As a result, the electrochemical characteristics of the cathode materials obtained using the single-stage scheme are improved. Comparison of the cathode materials obtained in this work with commercial samples produced in China indicates that the selected roasting conditions make it possible to obtain products that largely correspond to the level on the world market of lithium-ion batteries.
Ключевые слова Lithium-ion battery, cathode active material precursor, cathode active material, morphology, scanning electron microscopy, X-ray fluorescence analysis, granulometric composition, high-temperature roasting, electrochemical characteristics
Библиографический список

1. Savina A. A., Boev A. O., Orlova E. D., Morozov A. V. et al. Nickel is a key element of the energy of the future. Uspekhi khimii. 2023. Vol. 92, Iss. 7. RCR5086. DOI: 10.59761/RCR5086
2. Korneev S. I. Nickel and electric vehicle-joint prospects. Tsvetnye Metally. 2018. No. 7. pp. 19–26.
3. Antipov E. V., Abakumov A. M., Drozhzhin O. A., Pogozhev D. V. Lithiumion electrochemical energy storage devices: current state, problems and prospects for production development in Russia. Teploenergetika. 2019. No. 4. pp. 5–11.
4. Zhou D., Guo X., Zhang Q., Shi Y. et al. Nickel-based materials for advanced rechargeable batteries. Adv. Funct. Mater. 2022. Vol. 32. pp. 1–35.
5. Delmas C., Carlier D., Guignard M. The layered oxides in lithium and sodium-ion batteries: a solid-state chemistry approach. Advanced Energy Materials. 2021. Vol. 11, Iss. 2. pp. 2001201–2001220.
6. Kalyani P., Kalaiselvi N. Various aspects of LiNiO2 chemistry: A review. Science and Technology of Advanced Materials. 2005. Vol. 6. pp. 689–703.
7. Ohzuku T., Ueda A., Nagayama M. Electrochemistry and structural chemistry of LiNiO2 (R3m) for 4V secondary lithium cells. J. Electrochem. Soc. 1993. Vol. 140. pp. 1862–1870.
8. Julien C., Nazri G. A., Rougier A. Electrochemical performances of layered LiM1–yM'yO2 (M = Ni, Co; M' = Mg, Al, B) oxides in lithium batteries. Solid State Ionics. 2000. Vol. 135, Iss. 1-4. pp. 121–130.
9. Yang X. Q., Sun X., McBreen J. Structural changes and thermal stability: in situ X-ray diffraction studies of a new cathode material LiMg0.125Ti0.125Ni0.75O2. Electrochem. Commun. 2000. Vol. 2, Iss. 10. pp. 733–737.
10. Kim J., Amine K. The effect of tetravalent titanium substitution in LiNi1–xTixO2 (0.025< x <0.2) system. Electrochem. Commun. 2001. Vol. 3, Iss. 2. pp. 52–55.
11. Yan-Hui Chen, Jing Zhang, Yi Li, Yong-Fan Zhang et al. Effects of doping high-valence transition metal (V, Nb and Zr) ions on the structure and electrochemical performance of LIB cathode material LiNi0.8Co0.1Mn0.1O2. Phys. Chem. Chem. Phys. 2021. Vol. 23, Iss. 19. pp. 11528–11537.
12. Eftekhari A. Future lithium-ion batteries. The Royal Society of Chemistry. 2019. p. 48. DOI: 10.1039/9781788016124.
13. Ashton T. E., Baker P. J., Sotelo-Vazquez C., Footer C. J. M. et al. Stoichiometrically driven disorder and local diffusion in NMC cathodes. J. Mater. Chem. A. 2021. No. 9. pp. 10477–10486.
14. Dahn J. R., von Sacken U., Michal C. A. Structure and electrochemistry of Li1-yNiO2 and a new Li2NiO2 phase with the Ni(OH)2 structure. Solid State Ionics. 1990. Vol. 44, Iss. 1-2. pp. 87–97.
15. Li W., Erickson E. M., Manthiram A. High-nickel layered oxide cathodes for lithium-based automotive batteries. Nat. Energy. 2020. Vol. 5. pp. 26–34.
16. Savina A. A., Abakumov A. M. Benchmarking the electrochemical parame ters of the LiNi0.8Mn0.1Co0.1O2 positive electrode material for Li-ion batteries. Heliyon. 2023. Vol. 9. e21881. pp. 1–11.
Language of full-text русский
Полный текст статьи Получить
Назад