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Investigation on Purification of Saturated LiNO3 Solution Using Titanium Phosphate Ion Exchanger: Kinetics Study

Lithium compounds are of high interest to many industries. The presence of undesirable impurities in Li precursors leads to uncontrolled change in the functional properties of final compounds. Therefore, the development of reliable methods for lithium salt purification is considered a key factor for...

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Published in:	International journal of molecular sciences 2022-11, Vol.23 (21), p.13416
Main Authors:	Maslova, Marina, Ivanenko, Vladimir, Evstropova, Polina, Mudruk, Natalia, Gerasimova, Lidia
Format:	Article
Language:	English
Subjects:	Adsorption Carbon dioxide Chromium Cobalt Diffusion rate Electronic structure Equilibrium Functional groups Impurities Ion exchangers Kinetics Lithium Lithium compounds lithium nitrate Manganese ions Metal ions Metals Optics Phosphates Purification Salts Sorbents Sorption Titanium titanium phosphate transition metal ions Trivalent chromium
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creator	Maslova, Marina Ivanenko, Vladimir Evstropova, Polina Mudruk, Natalia Gerasimova, Lidia
description	Lithium compounds are of high interest to many industries. The presence of undesirable impurities in Li precursors leads to uncontrolled change in the functional properties of final compounds. Therefore, the development of reliable methods for lithium salt purification is considered a key factor for their application in various industries. This work focuses on the application of a titanium phosphate ion exchanger (Li-TiOP) toward Cu2+, Co2+, Mn2+, Ni2+, and Cr3+ ions in the purification of a saturated LiNO3 solution. The sorption kinetics of the selected ions, considering external and internal mass transfer, as well as chemical interaction, were deeply studied. The kinetic study showed that the values of intraparticle diffusion rate and effective diffusion coefficients for the studied ions decreased in the following order: Cr(III) ˃ Cu(II) Mn(II) ˃ Co(II) ˃ Ni(II). For all the selected ions, chemical interaction was described with a pseudo-second-order reaction model. The sorption kinetics were controlled by the size of the solvated metal ion, its effective charge, the electronic structure of the adsorbed ion, and the interaction with the functional groups of the sorbent. Due to fast kinetics, the high degree of removal of trace quantities of the impurities this material gives it consideration as a promising sorbent for the deep purification of lithium salts.
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The sorption kinetics were controlled by the size of the solvated metal ion, its effective charge, the electronic structure of the adsorbed ion, and the interaction with the functional groups of the sorbent. Due to fast kinetics, the high degree of removal of trace quantities of the impurities this material gives it consideration as a promising sorbent for the deep purification of lithium salts.</abstract><cop>Basel</cop><pub>MDPI AG</pub><pmid>36362198</pmid><doi>10.3390/ijms232113416</doi><orcidid>https://orcid.org/0000-0003-1280-5554</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Adsorption Carbon dioxide Chromium Cobalt Diffusion rate Electronic structure Equilibrium Functional groups Impurities Ion exchangers Kinetics Lithium Lithium compounds lithium nitrate Manganese ions Metal ions Metals Optics Phosphates Purification Salts Sorbents Sorption Titanium titanium phosphate transition metal ions Trivalent chromium
title	Investigation on Purification of Saturated LiNO3 Solution Using Titanium Phosphate Ion Exchanger: Kinetics Study
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