电化学电流时间瞬态的成核和生长速率的反卷积

R. Deutscher, S. Fletcher
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引用次数: 20

摘要

本文提出了两种新的算法,用于从电化学电流时间瞬态中解卷积成核和生长速率。第一种方法称为Bootstrap,是基于逐次逼近的方法。第二种称为简单拟合,并利用基于单纯形法的曲线拟合过程。两者都能够提供晶体数量作为时间函数的数值估计,在存在明显噪声的情况下,精度优于2%。这种算法的优点是,在标准方法无法实现的情况下,它们能产生准确的输出。特别是,即使晶体生长在测量的时间尺度上从界面控制切换到扩散控制,也可以确定晶体的数量与时间的关系。在锌在碳上成核和铅在碳上成核两个实际系统上验证了算法的有效性。在这两种情况下,在晶体生长速率随时间变化的情况下,容易观察到非稳定的成核状态。此外,还发现了一种新的现象,并建议将其命名为“成核持久性”。这是在过电位迅速降低后高成核率的短暂延续。这种现象是由于电极表面微观核的尺寸分布缓慢调整所致。有趣的是,成核持久性的存在使双电位步进技术失效,该技术以前被认为是观察电化学成核和生长的标准方法。最后简要介绍了成核持久性的数学理论。
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The deconvolution of nucleation and growth rates from electrochemical current–time transients
Two new algorithms have been developed for the deconvolution of nucleation and growth rates from electrochemical current–time transients. The first is called Bootstrap, and is based on the method of successive approximations. The second is called Simplefit, and utilizes a curve-fitting procedure based on the simplex method. Both are able to provide numerical estimates of the number of crystals as a function of time, to better than 2% accuracy, in the presence of significant noise. The advantage of the algorithms is that they produce accurate output under conditions where standard methods fail. In particular, the number of crystals versus time can be determined even when crystal growth switches from interfacial control to diffusion control on the timescale of measurements. The efficacy of the algorithms is demonstrated on two real systems, namely the nucleation of zinc on carbon, and the nucleation of lead on carbon. In both cases non-steady states of nucleation are readily observed in the presence of time-varying crystal growth rates. In addition, a new phenomenon is seen for which the name ''nucleation persistence'' is suggested. This is the transient continuation of a high rate of nucleation after a rapid decrease in overpotential. The phenomenon is attributed to the slow readjustment of the size distribution of microscopic nuclei on the electrode surface. Interestingly, the existence of nucleation persistence invalidates the double potential step technique, which has previously been regarded as the standard method for observing electrochemical nucleation and growth. Finally, the mathematical theory of nucleation persistence is briefly sketched.
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