Influence Mechanism of Precursor Crystallinity on Electrochemical Performance of LiFePO₄/C Cathode Material

Abstract: Determining the impact of precursor properties is essential for the performance regulation of LiFePO4 cathode material prepared by carbothermic reduction. In this study, FePO4 with different crystallinities, as precursors, was obtained at various precalcinating temperatures and reduced to form LiFePO4/C to quantitatively investigate crystallinity’s influence. The characterization and molecular dynamics (MD) simulation results showed that the crystallinity of FePO4 increased markedly with a higher dehydration t… Show more

“…Lithium-ion diffusion in LFP is preferably one-dimensional along the b -axis. , It is evident that the nanostructure facilitates shorter ion diffusion paths, resulting in high efficiency. , Various methods have been developed to prepare nanostructure LFP particles to facilitate Li + diffusion, including hydrothermal/solvothermal, , sol–gel, and hard-templating approaches. − Surface conductive coating and ion doping are complementally used to enhance the migration of electrons. − However, the high-performance nanostructured LFP suffers from low tap density and volumetric energy density limitations . With these drawbacks, extensive studies have been initiated to explore novel LFP nanostructures.…”

Novel Synthesis of 3D Mesoporous FePO₄ from Electroflocculation of Iron Filings as a Precursor of High-Performance LiFePO₄/C Cathode for Lithium-Ion Batteries

“…Lithium-ion diffusion in LFP is preferably one-dimensional along the b -axis. , It is evident that the nanostructure facilitates shorter ion diffusion paths, resulting in high efficiency. , Various methods have been developed to prepare nanostructure LFP particles to facilitate Li + diffusion, including hydrothermal/solvothermal, , sol–gel, and hard-templating approaches. − Surface conductive coating and ion doping are complementally used to enhance the migration of electrons. − However, the high-performance nanostructured LFP suffers from low tap density and volumetric energy density limitations . With these drawbacks, extensive studies have been initiated to explore novel LFP nanostructures.…”

Novel Synthesis of 3D Mesoporous FePO₄ from Electroflocculation of Iron Filings as a Precursor of High-Performance LiFePO₄/C Cathode for Lithium-Ion Batteries

“…With the shortage and increasing price of fossil energy, the wide application of lithium-ion batteries is of great significance to our country because of their low price, high power, and energy density. − As an important part of lithium-ion batteries (LIBs), negative materials are crucial to the energy storage performance. At present, the commercial graphite anode has reached the limit of its theoretical energy density and power density, − which is difficult to further break through.…”

Facilely Fabricating V₂O₃@C Nanosheets Grown on rGO as High-Performance Negative Materials for Lithium-Ion Batteries by Adjusting Surface Tension

Enhancement of uniformity and performance of LiFePO4/C cathode material prepared via a continuous rotating reactor