Electrochemical reaction mechanism of amorphous iron selenite with ultrahigh rate and excellent cyclic stability performance as new anode material for lithium-ion batteries

Keyphrases

• Lithium-ion Battery 100%
• Selenite 100%
• Stability Performance 100%
• New Anode Material 100%
• Electrochemical Reaction Mechanism 100%
• High Cyclic Stability 100%
• Ultrahigh Rate 100%
• Amorphous Iron 100%
• Low Temperature 25%
• Heterostructure 25%
• Active Sites 25%
• High Current Density 25%
• First Cycle 25%
• Iron Oxide 25%
• Li + 25%
• Metal Oxide 25%
• Nanocrystals 25%
• Reaction Mechanism 25%
• Anode Material 25%
• Lithium-ion 25%
• Reversible Reaction 25%
• Composite Electrode 25%
• Lithium Oxide 25%
• High Reversible Capacity 25%
• Li-ion 25%
• Carbon Materials 25%
• High Capacity 25%
• Interfacial Coupling 25%
• Metal Selenides 25%
• Metal Selenite 25%
• Iron Selenide 25%
• FeSe2 25%
• Ion Transportation 25%
• Electrochemical Kinetic Property 25%
• Anode Composition 25%

Material Science

• Lithium Ion Battery 100%
• Anode Material 100%
• Electrochemical Reaction 100%
• Lithium Ion 100%
• Density 50%
• Heterojunction 50%
• Oxidation Reaction 50%
• Metal Oxide 50%
• Anode 50%
• Phase Composition 50%