Can vanadium be substituted into LiFePO4?

Fredrick Omenya; Natasha A. Chernova; Shailesh Upreti; Peter Y. Zavalij; Kyung Wan Nam; Xiao Qing Yang; M. Stanley Whittingham

doi:10.1021/cm2017032

Can vanadium be substituted into LiFePO₄?

Fredrick Omenya
, Natasha A. Chernova
, Shailesh Upreti
, Peter Y. Zavalij
, Kyung Wan Nam
, Xiao Qing Yang
, M. Stanley Whittingham

Department of Energy and Materials Engineering

Research output: Contribution to journal › Article › peer-review

119 Scopus citations

Abstract

Vanadium is shown to substitute for iron in the olivine LiFePO₄ up to at least 10 mol %, when the synthesis is carried out at 550 °C. In the solid solution LiFe_1-3y/2V_yPO₄, the a and b lattice parameters and cell volume decrease with increasing vanadium content, while the c lattice parameter increases slightly. However, when the synthesis is performed at 650 °C, a NASICON phase, Li₃V₂(PO ₄)₃, is also formed, showing that solid solution is a function of the synthesis temperature. X-ray absorption near-edge structure indicates vanadium is in the 3+ oxidation state and in an octahedral environment. Magnetic studies reveal a shift of the antiferromagnetic ordering transition toward lower temperatures with increasing vanadium substitution, confirming solid solution formation. The addition of vanadium enhances the electrochemical performance of the materials especially at high current densities.

Original language	English
Pages (from-to)	4733-4740
Number of pages	8
Journal	Chemistry of Materials
Volume	23
Issue number	21
DOIs	https://doi.org/10.1021/cm2017032
State	Published - 8 Nov 2011

Keywords

electrochemical properties
Olivine phosphates
vanadium substitution

Access to Document

10.1021/cm2017032

Cite this

@article{f7783054d5764c1389c8a1e286f39f62,

title = "Can vanadium be substituted into LiFePO4?",

abstract = "Vanadium is shown to substitute for iron in the olivine LiFePO4 up to at least 10 mol \%, when the synthesis is carried out at 550 °C. In the solid solution LiFe1-3y/2VyPO4, the a and b lattice parameters and cell volume decrease with increasing vanadium content, while the c lattice parameter increases slightly. However, when the synthesis is performed at 650 °C, a NASICON phase, Li3V2(PO 4)3, is also formed, showing that solid solution is a function of the synthesis temperature. X-ray absorption near-edge structure indicates vanadium is in the 3+ oxidation state and in an octahedral environment. Magnetic studies reveal a shift of the antiferromagnetic ordering transition toward lower temperatures with increasing vanadium substitution, confirming solid solution formation. The addition of vanadium enhances the electrochemical performance of the materials especially at high current densities.",

keywords = "electrochemical properties, Olivine phosphates, vanadium substitution",

author = "Fredrick Omenya and Chernova, \{Natasha A.\} and Shailesh Upreti and Zavalij, \{Peter Y.\} and Nam, \{Kyung Wan\} and Yang, \{Xiao Qing\} and Whittingham, \{M. Stanley\}",

year = "2011",

month = nov,

day = "8",

doi = "10.1021/cm2017032",

language = "English",

volume = "23",

pages = "4733--4740",

journal = "Chemistry of Materials",

issn = "0897-4756",