Correlation between Li + adsorption capacity and the preparation conditions of spinel lithium manganese precursor

Spinel lithium manganese oxides can be used as Li + adsorbent with topotactical extraction of lithium. In this paper, the solid state methods were introduced to prepare spinel lithium manganese precursors with Li 2CO 3 and LiOH·H 2O as different Li sources. The Li + uptake was studied to clarify the...

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Published inSolid state ionics Vol. 177; no. 17; pp. 1421 - 1428
Main Authors Wang, Lu, Ma, Wei, Liu, Ru, Li, Hai Yan, Meng, Chang Gong
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.07.2006
Subjects
Adsorption
Ion sieve
Lithium
Spinel manganese oxide
Spinel manganese oxide
Lithium
Ion sieve
Adsorption
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Abstract Spinel lithium manganese oxides can be used as Li + adsorbent with topotactical extraction of lithium. In this paper, the solid state methods were introduced to prepare spinel lithium manganese precursors with Li 2CO 3 and LiOH·H 2O as different Li sources. The Li + uptake was studied to clarify the correction between Li + adsorption capacity and the preparation conditions of precursors, including different Li sources, Li/Mn mole ratios and heating time. The results indicated that the Li +-extracted materials prepared with LiOH·H 2O and MnCO 3 usually have higher Li + adsorption capacity than Li 2CO 3 and MnCO 3, and an ascending trend was found in Li + uptake with increasing Li/Mn mole ratio in the preparation of the precursor, but it is not proportional. The Mn 2O 3 impurities could be the primary reason for decreasing Li + adsorption capacity. Furthermore, it is concluded that the Li +-extracted materials obtained from spinel manganese oxides synthesized with Li/Mn = 1.0 can serve as selective Li + absorbents due to its high selectivity and large adsorption capacity.
AbstractList Spinel lithium manganese oxides can be used as Li+ adsorbent with topotactical extraction of lithium. In this paper, the solid state methods were introduced to prepare spinel lithium manganese precursors with Li2CO3 and LiOH*H2O as different Li sources. The Li+ uptake was studied to clarify the correction between Li+ adsorption capacity and the preparation conditions of precursors, including different Li sources, Li/Mn mole ratios and heating time. The results indicated that the Li+-extracted materials prepared with LiOH*H2O and MnCO3 usually have higher Li+ adsorption capacity than Li2CO3 and MnCO3, and an ascending trend was found in Li+ uptake with increasing Li/Mn mole ratio in the preparation of the precursor, but it is not proportional. The Mn2O3 impurities could be the primary reason for decreasing Li+ adsorption capacity. Furthermore, it is concluded that the Li+-extracted materials obtained from spinel manganese oxides synthesized with Li/Mn=1.0 can serve as selective Li+ absorbents due to its high selectivity and large adsorption capacity.
Spinel lithium manganese oxides can be used as Li + adsorbent with topotactical extraction of lithium. In this paper, the solid state methods were introduced to prepare spinel lithium manganese precursors with Li 2CO 3 and LiOH·H 2O as different Li sources. The Li + uptake was studied to clarify the correction between Li + adsorption capacity and the preparation conditions of precursors, including different Li sources, Li/Mn mole ratios and heating time. The results indicated that the Li +-extracted materials prepared with LiOH·H 2O and MnCO 3 usually have higher Li + adsorption capacity than Li 2CO 3 and MnCO 3, and an ascending trend was found in Li + uptake with increasing Li/Mn mole ratio in the preparation of the precursor, but it is not proportional. The Mn 2O 3 impurities could be the primary reason for decreasing Li + adsorption capacity. Furthermore, it is concluded that the Li +-extracted materials obtained from spinel manganese oxides synthesized with Li/Mn = 1.0 can serve as selective Li + absorbents due to its high selectivity and large adsorption capacity.
Author Meng, Chang Gong
Ma, Wei
Liu, Ru
Li, Hai Yan
Wang, Lu
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  fullname: Meng, Chang Gong
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Lithium
Ion sieve
Adsorption
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Snippet Spinel lithium manganese oxides can be used as Li + adsorbent with topotactical extraction of lithium. In this paper, the solid state methods were introduced...
Spinel lithium manganese oxides can be used as Li+ adsorbent with topotactical extraction of lithium. In this paper, the solid state methods were introduced to...
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SubjectTerms Adsorption
Ion sieve
Lithium
Spinel manganese oxide
Title Correlation between Li + adsorption capacity and the preparation conditions of spinel lithium manganese precursor
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