Ryuichi Natsui scite author profile

A new pyrophosphate compound Li(2)FeP(2)O(7) was synthesized by a conventional solid-state reaction, and its crystal structure was determined. Its reversible electrode operation at ca. 3.5 V vs Li was identified with the capacity of a one-electron theoretical value of 110 mAh g(-1) even for ca. 1 μm particles without any special efforts such as nanosizing or carbon coating. Li(2)FeP(2)O(7) and its derivatives should provide a new platform for related lithium battery electrode research and could be potential competitors to commercial olivine LiFePO(4), which has been recognized as the most promising positive cathode for a lithium-ion battery system for large-scale applications, such as plug-in hybrid electric vehicles.

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Kinetics of Nucleation and Growth in Two-Phase Electrochemical Reaction of Li_xFePO₄

Oyama

et al. 2012

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The kinetics of a two-phase electrochemical reaction in Li x FePO 4 was investigated by potential-step chronoamperometry under various experimental conditions: amplitude of potential step, direction of potential step, particle size, and thickness of composite electrodes. Only under a small potential step (10 mV) applied to large Li x FePO 4 particles (203 nm), the chronoamperogram showed a momentary current increase, followed by gradual decline, indicating that the nucleation and growth governed the electrode kinetics. In that condition, the chronoamperogram was analyzed with the Kolmogorov−Johnson−Mehl−Avrami (KJMA) model, which describes the kinetics of phase transition. The obtained Avrami exponent of ca. 1.1 indicates that the phase transition proceeds with a one-dimensional phase-boundary movement, which is consistent with the previously reported mechanism. From the temperature dependence of the obtained rate constant, the activation energy of the phase-boundary movement in Li x FePO 4 was estimated to be 42 and 40 kJ mol −1 in cathodic and anodic reactions, respectively.

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Reversible Li storage for nanosize cation/anion-disordered rocksalt-type oxyfluorides: LiMoO 2 – x LiF (0 ≤ x ≤ 2) binary system

Takeda

Hoshino

Xie

et al. 2017

Journal of Power Sources

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Improved Electrode Performance of Lithium-Excess Molybdenum Oxyfluoride: Titanium Substitution with Concentrated Electrolyte

Takeda

Ikeuchi

Natsui

et al. 2019

ACS Appl. Energy Mater.

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A titanium-substituted lithium-excess molybdenum oxyfluoride, Li2.1–y Ti0.2Mo0.7O2F, is synthesized by mechanical milling and tested as a positive electrode material in a conventional carbonate-based electrolyte or concentrated electrolyte. Reversibility as the electrode material is significantly improved by suppression of dissolution of the molybdenum oxyfluoride on electrochemical cycles. Li2.1–y Ti0.2Mo0.7O2F delivers a reversible capacity of 265 mA h g–1 after 30 cycles at a rate of 50 mA g–1 with concentrated electrolyte. This finding contributes to the development of high-energy and long-cycle-life rechargeable lithium batteries with lithium-excess metal oxyfluorides in the future.

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Ryuichi Natsui

New Lithium Iron Pyrophosphate as 3.5 V Class Cathode Material for Lithium Ion Battery

Kinetics of Nucleation and Growth in Two-Phase Electrochemical Reaction of Li_xFePO₄

Reversible Li storage for nanosize cation/anion-disordered rocksalt-type oxyfluorides: LiMoO 2 – x LiF (0 ≤ x ≤ 2) binary system

Improved Electrode Performance of Lithium-Excess Molybdenum Oxyfluoride: Titanium Substitution with Concentrated Electrolyte

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Ryuichi Natsui

New Lithium Iron Pyrophosphate as 3.5 V Class Cathode Material for Lithium Ion Battery

Kinetics of Nucleation and Growth in Two-Phase Electrochemical Reaction of LixFePO4

Reversible Li storage for nanosize cation/anion-disordered rocksalt-type oxyfluorides: LiMoO 2 – x LiF (0 ≤ x ≤ 2) binary system

Improved Electrode Performance of Lithium-Excess Molybdenum Oxyfluoride: Titanium Substitution with Concentrated Electrolyte

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Product

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Kinetics of Nucleation and Growth in Two-Phase Electrochemical Reaction of Li_xFePO₄