The role of impurities on electrochemical properties of LiFePO4 cathode material

LiFePO4, one of the attractive cathode materials for lithium ion batteries, is obtained by lithiation of pre-synthesized FePO4 using lithium carbonate as lithium source. Inexpensive reducing agent glucose was used for the reduction process. Glucose acted as a conductive additive as well. Lithium ion...

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Bibliographic Details
Published in:Ceramics international 2013-05, Vol.39, p.S647-S651
Main Authors: Yoon, Man-Soon, Islam, Mobinul, Ur, Soon-Chul
Format: Article
Language:English
Subjects:
B. Composites
B. Impurities
Carbon
Ceramics
Coating
Crystallinity
E. Batteries
Glucose
Impurities
Lithium
Reduction
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Summary:LiFePO4, one of the attractive cathode materials for lithium ion batteries, is obtained by lithiation of pre-synthesized FePO4 using lithium carbonate as lithium source. Inexpensive reducing agent glucose was used for the reduction process. Glucose acted as a conductive additive as well. Lithium ion conductive impurity phase can be attributed to the capacity improvement in LiFePO4 with carbon coating. The off-stoichiometric LixFePO4 (x=1.005, 1.010) was synthesized to generate a conductive pyrophosphate layer. An electron conductive layer with carbon coating was also concurrently formed by carbothermal reduction of glucose. It is observed that the electrochemical property improves with increasing amount of lithium pyrophosphate impurity phase. This observable fact may be due to accelerating lithium ion diffusion on the lithium ion conductive lithium pyrophosphate layer. XRD and SEM observation show that the LixFePO4/C composite has good crystallinity and well-dispersed particles of 200–300nm size. The LixFePO4/C (x=1.010) composite shows a high discharge capacity of 150mAhg−1 and 136mAhg−1 at rates of 0.1C and 1C respectively with satisfactory capacity retention.
ISSN:0272-8842
1873-3956
DOI:10.1016/j.ceramint.2012.10.154