用机器学习研究实验晶体结构的一般力场。用FlexCryst计算分子间吉布斯能。

IF 1.9 4区 材料科学 Q3 CHEMISTRY, MULTIDISCIPLINARY Acta Crystallographica Section A: Foundations and Advances Pub Date : 2023-03-01 DOI:10.1107/S2053273323000268
Detlef Walter Maria Hofmann, Liudmila Nikolaevna Kuleshova
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引用次数: 0

摘要

将机器学习应用于剑桥结构数据库(CSD)的实验晶体结构,推导出所有可用原子类型的分子间力场(一般力场)。得到的一般力场的原子间势可以快速准确地计算分子间吉布斯能。该方法基于关于吉布斯能量的三个假设:晶格能量必须低于零,晶体结构必须是局部最小值,如果可行,实验和计算的晶格能量必须一致。然后根据这三种条件对参数化的一般力场进行验证。首先,将实验点阵能与计算点阵能进行比较。观察到的误差与实验误差的数量级相当。其次,计算了CSD中所有结构的吉布斯晶格能。在99.86%的情况下,它们的能量值低于零。最后,对500个随机结构进行了最小化,并对密度和能量的变化进行了分析。密度的平均误差在4.06%以下,能量的平均误差在5.7%以下。得到的一般力场在数小时内计算出25941个已知晶体结构的吉布斯晶格能。由于吉布斯能定义反应能,计算出的能量可以用来预测晶体的化学物理性质,例如,共晶的形成、多晶的稳定性和溶解度。
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A general force field by machine learning on experimental crystal structures. Calculations of intermolecular Gibbs energy with FlexCryst.

Machine learning was employed on the experimental crystal structures of the Cambridge Structural Database (CSD) to derive an intermolecular force field for all available types of atoms (general force field). The obtained pairwise interatomic potentials of the general force field allow for the fast and accurate calculation of intermolecular Gibbs energy. The approach is based on three postulates regarding Gibbs energy: the lattice energy must be below zero, the crystal structure must be a local minimum, and, if available, the experimental and the calculated lattice energy must coincide. The parametrized general force field was then validated regarding these three conditions. First, the experimental lattice energy was compared with the calculated energies. The observed errors were found to be in the order of experimental errors. Second, Gibbs lattice energy was calculated for all structures available in the CSD. Their energy values were found to be below zero in 99.86% of the cases. Finally, 500 random structures were minimized, and the change in density and energy was examined. The mean error in the case of density was below 4.06%, and for energy it was below 5.7%. The obtained general force field calculated Gibbs lattice energies of 259 041 known crystal structures within a few hours. Since Gibbs energy defines the reaction energy, the calculated energy can be used to predict chemical-physical properties of crystals, for instance, the formation of co-crystals, polymorph stability and solubility.

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来源期刊
Acta Crystallographica Section A: Foundations and Advances
Acta Crystallographica Section A: Foundations and Advances CHEMISTRY, MULTIDISCIPLINARYCRYSTALLOGRAPH-CRYSTALLOGRAPHY
CiteScore
2.60
自引率
11.10%
发文量
419
期刊介绍: Acta Crystallographica Section A: Foundations and Advances publishes articles reporting advances in the theory and practice of all areas of crystallography in the broadest sense. As well as traditional crystallography, this includes nanocrystals, metacrystals, amorphous materials, quasicrystals, synchrotron and XFEL studies, coherent scattering, diffraction imaging, time-resolved studies and the structure of strain and defects in materials. The journal has two parts, a rapid-publication Advances section and the traditional Foundations section. Articles for the Advances section are of particularly high value and impact. They receive expedited treatment and may be highlighted by an accompanying scientific commentary article and a press release. Further details are given in the November 2013 Editorial. The central themes of the journal are, on the one hand, experimental and theoretical studies of the properties and arrangements of atoms, ions and molecules in condensed matter, periodic, quasiperiodic or amorphous, ideal or real, and, on the other, the theoretical and experimental aspects of the various methods to determine these properties and arrangements.
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