We present a machine-learning approach, based on normalizing flows, for modelling atomic solids. Our model transforms an analytically tractable base distribution into the target solid without requiring ground-truth samples for training. We report Helmholtz free energy estimates for cubic and hexagonal ice modelled as monatomic water as well as for a truncated and shifted Lennard-Jones system, and find them to be in excellent agreement with literature values and with estimates from established baseline methods. We further investigate structural properties and show that the model samples are nearly indistinguishable from the ones obtained with molecular dynamics. Our results thus demonstrate that normalizing flows can provide high-quality samples and free energy estimates without the need for multi-staging.
翻译:我们提出一种基于正常流流的机器学习方法,用于模拟原子固体。我们的模型将分析可移动的基础分布转化为固态目标,而不需要地面实况样本来进行培训。我们报告赫尔默尔茨(Helmholtz)对立方冰和六边形冰的免费能源估算,它们以单质水和脱节和转移的伦纳德-琼斯系统为模型,发现它们与文献价值和既定基线方法的估算非常一致。我们进一步调查了结构属性,并表明模型样本几乎无法区分以分子动力获得的样本。因此,我们的结果表明,正常流可以提供高质量的样本和免费能源估算,而无需多用途。