C. Julien scite author profile

International audienceDeviation from ideal stoichiometry of LiFePO4 has been investigated. Any attempt to increase the Li concentration of samples prepared either by the precursor precipitation route or by the continuous aqueous precursor synthesis route results in the formation of lithium phosphate impurity, in addition to stoichiometric LiFePO4 free of any Li vacancy. On the other hand, Li-deficient homogeneous solid solutions of composition Li1−2xFexFePO4 could be obtained. For x ≥ 0.06, however, a sarcopside impurity phase is formed. Investigations of structural properties allow us to define the defect responsible for the solid solution as Fe•Li + V′Li in the Krger−Vink notation. Because the chemical formula of the sarcopside is obtained by writing x = 1/2 in the chemical formula of the solid solution, this impurity phase can be viewed as a condensation of the Fe•Li + V′Li defects. Magnetic measurements show that isolated lithium vacancies V′Li are also diluted in the Li1−2xFexFePO4 matrix. The negative charge of the isolated V′Li is compensated by the valence change Fe2+ → Fe3+ of an iron ion in its vicinity, forming a small magnetic polaron that is detected by magnetic measurements. The concentration of such polarons, however, remains very small as it saturates to a concentration of 0.2−0.3 mol %, much smaller than the concentration x in V′Li bound to Fe•Li. The electrochemical features are significantly damaged by the Fe•Li defects that block the diffusion of lithium along the corresponding channel, while the Li3PO4 only acts as an inert mass

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Characterization of Na-based phosphate as electrode materials for electrochemical cells

Zaghib¹,

Trottier²,

Hovington³

et al. 2011

Journal of Power Sources

204

131

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New Lithium Metal Polymer Solid State Battery for an Ultrahigh Energy: Nano C-LiFePO₄ versus Nano Li_1.2V₃O₈

et al. 2015

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Novel lithium metal polymer solid state batteries with nano C-LiFePO4 and nano Li1.2V3O8 counter-electrodes (average particle size 200 nm) were studied for the first time by in situ SEM and impedance during cycling. The kinetics of Li-motion during cycling is analyzed self-consistently together with the electrochemical properties. We show that the cycling life of the nano Li1.2V3O8 is limited by the dissolution of the vanadium in the electrolyte, which explains the choice of nano C-LiFePO4 (1300 cycles at 100% DOD): with this olivine, no dissolution is observed. In combination with lithium metal, at high loading and with a stable SEI an ultrahigh energy density battery was thus newly developed in our laboratory.

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C. Julien

Nonstoichiometric LiFePO₄: Defects and Related Properties

Characterization of Na-based phosphate as electrode materials for electrochemical cells

New Lithium Metal Polymer Solid State Battery for an Ultrahigh Energy: Nano C-LiFePO₄ versus Nano Li_1.2V₃O₈

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C. Julien

Nonstoichiometric LiFePO4: Defects and Related Properties

Characterization of Na-based phosphate as electrode materials for electrochemical cells

New Lithium Metal Polymer Solid State Battery for an Ultrahigh Energy: Nano C-LiFePO4 versus Nano Li1.2V3O8

Contact Info

Product

Resources

About

Nonstoichiometric LiFePO₄: Defects and Related Properties

New Lithium Metal Polymer Solid State Battery for an Ultrahigh Energy: Nano C-LiFePO₄ versus Nano Li_1.2V₃O₈