[N(C4H9)4]BF4 / (110) α-Al2O3界面的分子动力学模拟

Q4 Materials Science

Chimica Techno Acta Pub Date : 2023-08-16 DOI:10.15826/chimtech.2023.10.3.08

I. Gainutdinov, N. Uvarov

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引用次数: 0

摘要

为了揭示盐/氧化物界面对盐的结构和性能的影响，采用MD计算机模拟研究了纯盐[N4]BF4及其与a- al2o3(110)表面接触的盐的结构和输运性质。分析了盐冷却过程中离子径向分布函数及其均方位移随温度的变化规律。人们发现，在所有的情况下，阴离子比阳离子更具流动性。[N4]BF4熔相在420 K接近实验熔点时趋于结晶。位于[N4]BF4/(110)Al2O3界面的盐表现出较高的阴离子自扩散系数，比纯盐高1.2-2个数量级。这种效应可能是由于在5nm的特征厚度内形成层状原子结构引起的。尽管有结构，但盐的结构是无定形的，没有观察到与结晶相关的影响。MD模拟结果与先前在[N4]BF4-Al2O3纳米复合材料中观察到的电导率增强的实验效果一致。

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Molecular dynamic simulation of the [N(C4H9)4]BF4 / (110) α-Al2O3 interface

The structure and transport properties of the pure salt [N4]BF4 and this salt located in the contact with the (110) surface of a-Al2O3 were studied using a MD computer simulation in order to reveal the effect of the salt/oxide interface on the structure and properties of the salt. The radial distribution functions of the ions and their mean square displacements were analyzed as a function of the temperature during the cooling of the salt. It was found that in all the cases anions are more mobile than cations. The molten phase of [N4]BF4 tends to crystallize at temperature 420 K which is close to the experimental melting point. The salt located in the [N4]BF4/(110)Al2O3 interface exhibits high values of anion self-diffusion coefficients which are higher by 1.2–2 orders of magnitude than in pure salt. This effect is likely to be caused by the formation of a layered atomic structure located within a characteristic thickness of 5 nm. Despite the structuring, the structure of the salt is amorphous, no crystallization-related effect is observed. The results of MD simulations agree with the experimental effect of the conductivity enhancement observed previously in [N4]BF4-Al2O3 nanocomposites.

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来源期刊

Chimica Techno Acta Chemical Engineering-Chemical Engineering (all)

CiteScore

1.00

自引率

0.00%

发文量

审稿时长

4 weeks