非谐性
计算机科学
人工神经网络
采样(信号处理)
原子间势
红外线的
分子动力学
集合(抽象数据类型)
训练集
数据集
谱线
数据点
统计物理学
人工智能
计算物理学
物理
计算化学
化学
光学
计算机视觉
量子力学
滤波器(信号处理)
程序设计语言
作者
Zeyuan Tang,Stefan T. Bromley,Bjørk Hammer
摘要
The use of machine learning (ML) in chemical physics has enabled the construction of interatomic potentials having the accuracy of ab initio methods and a computational cost comparable to that of classical force fields. Training an ML model requires an efficient method for the generation of training data. Here, we apply an accurate and efficient protocol to collect training data for constructing a neural network-based ML interatomic potential for nanosilicate clusters. Initial training data are taken from normal modes and farthest point sampling. Later on, the set of training data is extended via an active learning strategy in which new data are identified by the disagreement between an ensemble of ML models. The whole process is further accelerated by parallel sampling over structures. We use the ML model to run molecular dynamics simulations of nanosilicate clusters with various sizes, from which infrared spectra with anharmonicity included can be extracted. Such spectroscopic data are needed for understanding the properties of silicate dust grains in the interstellar medium and in circumstellar environments.
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