Study of the Inorganic Ion Exchanger Li3Mn0.25Ti0.5O3

Jin He Jiang

doi:10.4028/www.scientific.net/AMM.178-181.471

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 178-181Study of the Inorganic Ion Exchanger...

Study of the Inorganic Ion Exchanger Li₃Mn_0.25Ti_0.5O₃

Abstract:

Inorganic ion exchanger (Li3Mn0.25Ti0.5O3) with an inverse spinel structure was synthesized by solid state reaction crystallization method. The results showed that the Li+ extraction/insertion be progressed mainly by an ion-exchange mechanism. The acid treated samples had an ion exchange capacity of 9.2mmol/g for Li+.

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Periodical:

Applied Mechanics and Materials (Volumes 178-181)

Pages:

471-474

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.178-181.471

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Online since:

May 2012

Authors:

Jin He Jiang

Keywords:

Inverse Spinel-Type Metal Compound, Ion-Exchange Mechanism, Li₃Mn_0.25Ti_0.5O₃

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References

[1] S.C. Zhang, G.F. Zhou: Technological experiment on lithium extraction from bittern of salt lake by adsorption methode, J.Ion Exchange and Adsorption. 1998, 14(4):351

Google Scholar

[2] Sheng Yuan Jun, Zhi Yong Ji. Seawater Lithium research [J]. Sea Lake Salt and Chemical Industry, 2003, 32 (5): 29-33.

Google Scholar

[3] Sui Lian Luo, Wei Shan Li, Shi Zhou Qiu, et al. LiMn2O4 doped elements on the structure and properties [J]. Battery, 2001, 31 (1): 44-47.

Google Scholar

[4] G Q Liu, Y J Wang, Q Lu, et al . Synthesis and characterization of spinel type high-power cathode material LiMxMn2- xO4( M= Ni, Co, C r) [ J] . Journal of Physics and Chemistry of Solids , 2007, 68: 780-784.

Google Scholar