Mechanochemical synthesis of SnO-B2</sub>O3</sub> glassy anode materials for rechargeable lithium batteries

A. Hayashi; M. Nakai; H. Morimoto; T. Minami; M. Tatsumisago

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Mechanochemical synthesis of SnO-B2O3 glassy anode materials for rechargeable lithium batteries

机译：机械化学合成可再充电锂电池用SnO-B2 O3 玻璃态阳极材料

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The xSnO·(100 − x)B2O3 (0 ≦ x ≦ 80) glasses were successfully prepared by a mechanical milling technique. The glass with 40 mol% SnO showed the maximum glass transition temperature of 347°C. The SnO-B2O3 milled glasses consisted of both BO3 and BO4 units, and the fraction of BO4 units was maximized at the composition of 50 mol% SnO. The electrochemical properties of the milled glasses were examined using a simple three electrodes cell with a conventional liquid electrolyte. The glasses with high SnO content exhibited high charge capacities more than 1100 mAh g−1 and discharge capacities more than 700 mAh g−1 at the first cycle. The SnO-B2O3 milled glasses proved to work as anode materials for rechargeable lithium batteries.

机译：采用机械研磨技术成功制备了xSnO·（100-x）B2O3 （0≤x≤80）玻璃。 SnO含量为40摩尔％的玻璃的最高玻璃化转变温度为347℃。 SnO-B2 O3 磨碎的玻璃由BO3 和BO4 单元组成，并且BO4 单元的比例在50 mol％的组分中最大。锡使用具有常规液体电解质的简单三电极电池检查磨碎玻璃的电化学性能。 SnO含量高的玻璃在第一个循环中的充电容量大于1100 mAh g-1 ，放电容量大于700 mAh g-1 。 SnO-B2 O3 研磨玻璃被证明是可充电锂电池的负极材料。

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《Journal of Materials Science 》 |2004年第17期| 5361-5364| 共4页
作者
A. Hayashi; M. Nakai; H. Morimoto; T. Minami; M. Tatsumisago;
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Department of Applied Materials Science Graduate School of Engineering Osaka Prefecture University;

Department of Applied Materials Science Graduate School of Engineering Osaka Prefecture University;

Department of Applied Materials Science Graduate School of Engineering Osaka Prefecture University;

Department of Applied Materials Science Graduate School of Engineering Osaka Prefecture University;

Department of Applied Materials Science Graduate School of Engineering Osaka Prefecture University;

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8. Synthesis and Evaluation of New Cathode Materials for Rechargeable Lithium Batteries. Annual Report, April 26, 1976-September 15, 1977 [R] . Gupta, G. D. 1977

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Mechanochemical synthesis of SnO-B2O3 glassy anode materials for rechargeable lithium batteries

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