Chong-jun Bao scite author profile

As a new type of green power system, lithium ion battery has been widely developed in the field of new energy. Lithium manganese oxide has become a hot topic due to its low price, safety and pollution-free properties. In this paper, the research progress of positive electrode material LiMn2O4 for lithium ion batteries in recent years is reviewed, in addition, the structural properties, synthesis methods, existing problems and modification aspects of the material are described.

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Impact of H₂O on the Microscopic Oxidation Mechanism of Lollingite: Experimental and Theoretical Analyses

Zhang

Bao

Chen

et al. 2023

Langmuir

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Lollingite (FeAs2) is considered an arsenic-bearing mineral that is oxidized faster than arsenopyrite. The geometric configuration, chemical valence bond, and microscopic reaction of the oxidation on the surface of lollingite were systematically studied, which are of great significance for understanding the mechanism of oxidative dissolution. X-ray photoelectron spectroscopy (XPS) measurements and density functional theory (DFT) calculations were carried out to characterize the (101) surface oxidation process of lollingite under the O2/O2 + H2O conditions. XPS results confirmed that the participation of water molecules can promote the formation of abundant OH structures on the surface of lollingite, while the relative concentration of O, As(III), and Fe(III) increased. Moreover, the DFT results demonstrated that the (101) As-terminal plane of FeAs2 was the most stable surface with the lowest surface energy. H2O molecules were physically adsorbed onto the Fe atoms of the lollingite surface, while oxygen molecules can readily be adsorbed on the Fe–As2 site by chemical adsorption processes. The oxidation process of the lollingite surface with water includes the following mechanisms: adsorption, dissociation, formation of the hydrogen bond, and desorption. The dissociation of the H2O molecule into OH and H led to the hydroxylation of both Fe and As atoms and the formation of hydrogen bonding. The participation of H2O molecules can also reduce the reaction energy barrier and accelerate the oxidation reaction of the lollingite surface, especially as far as the water dissociation and formation of hydrogen bonds are concerned. According to PDOS data, there is considerable hybridization between the d orbitals of bonded Fe atoms and the p orbitals of O atoms, as well as between the p orbitals of bonded As atoms and the p orbitals of O atoms. Due to a strong propensity for orbital hybridization and bonding between the s orbitals of the H atoms in H2O molecules and the p orbitals of the O atoms on the (101) surface, water molecules have the ability to speed up the oxidation on the surface.

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Effects of pre-deformation mode and strain on creep aging bend-forming process of Al−Cu−Li alloy

Tang

Zhang

et al. 2020

Transactions of Nonferrous Metals Society of China

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Chong-jun Bao

Red mud-metakaolin based cementitious material for remediation of arsenic pollution: Stabilization mechanism and leaching behavior of arsenic in lollingite

Research Status of Spinel LiMn₂O₄ Cathode Materials for Lithium Ion Batteries

Impact of H₂O on the Microscopic Oxidation Mechanism of Lollingite: Experimental and Theoretical Analyses

Effects of pre-deformation mode and strain on creep aging bend-forming process of Al−Cu−Li alloy

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Chong-jun Bao

Red mud-metakaolin based cementitious material for remediation of arsenic pollution: Stabilization mechanism and leaching behavior of arsenic in lollingite

Research Status of Spinel LiMn2O4 Cathode Materials for Lithium Ion Batteries

Impact of H2O on the Microscopic Oxidation Mechanism of Lollingite: Experimental and Theoretical Analyses

Effects of pre-deformation mode and strain on creep aging bend-forming process of Al−Cu−Li alloy

Contact Info

Product

Resources

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Research Status of Spinel LiMn₂O₄ Cathode Materials for Lithium Ion Batteries

Impact of H₂O on the Microscopic Oxidation Mechanism of Lollingite: Experimental and Theoretical Analyses