In Situ Imaging of Lithium-Ion Batteries Via the Secondary Ion Mass Spectrometry

Journal of nanotechnology in engineering and medicine Pub Date : 2014-05-01 DOI:10.1115/1.4028010

C. ChiuHuang, Chuanzhen Zhou, H. Huang

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引用次数: 10

Abstract

To develop lithium-ion batteries with a high rate-capability and low cost, the prevention of capacity loss is one of major challenges, which needs to be tackled in the lithium-ion battery industry. During electrochemical processes, lithium ions diffuse from and insert into battery electrodes accompanied with the phase transformation, whereas ionic diffusivity and concentration are keys to the resultant battery capacity. In the current study, we compare voltage versus capacity of lithium-ion batteries at different current-rates (C-rates) discharging. Larger hysteresis and voltage fluctuations are observed in higher C-rate samples. We investigate origins of voltage fluctuations by quantifying lithium-ion intensity and distribution via a time-of-flight secondary ion mass spectrometry (ToF-SIMS). The result shows that for fully discharged samples, lithium-ion intensity and distribution are not C-rate dependent, suggesting different lithium-ion insertion mechanisms at a higher C-rate discharging might be solely responsible for the observed low frequency voltage fluctuation.

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锂离子电池的二次离子质谱原位成像

为了开发高倍率、低成本的锂离子电池，防止容量损失是锂离子电池行业需要解决的主要挑战之一。在电化学过程中，锂离子从电池电极扩散并插入到电池电极中，伴随着相变，而离子扩散率和浓度是最终电池容量的关键。在当前的研究中，我们比较了锂离子电池在不同电流率(c -rate)放电时的电压和容量。在高c率的样品中观察到较大的滞后和电压波动。我们通过飞行时间二次离子质谱法(ToF-SIMS)量化锂离子强度和分布来研究电压波动的起源。结果表明，对于完全放电的样品，锂离子的强度和分布与c倍率无关，表明在高c倍率放电时不同的锂离子插入机制可能是观察到的低频电压波动的唯一原因。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of nanotechnology in engineering and medicine

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