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引用次数: 0
摘要
在这项研究中,我们在密度泛函理论水平上利用周期性边界条件(DFT-PBC)模拟了五种分子晶体的光学旋转(OR)。我们将计算结果与实验测量结果进行了比较,结果表明其中三种晶体(酒石酸、苯齐尔和季戊四醇)的计算结果与实验数据半定量一致。对于另外两种晶体,即天冬氨酸和谷氨酸,计算数据与实验数据在质量上一致,但比实验数据小两个数量级。我们提供了一些支持理论预测的论据,并建议重新研究实验。我们还发现,X 射线实验数据中提供的 H 中心位置对于模拟 OR 来说不够可靠,如果允许 H 原子松弛,同时将较重的元素固定在实验位置上,则会得到更好的结果。用更好的函数和更大的基集与分子簇计算结果进行比较表明,分子间相互作用(用 PBC 技术再现)的作用与化学模型的选择同样重要,甚至更为重要。尽管目前采用的理论水平有限,但这些模拟为研究分子间相互作用对分子和材料的这一敏感电子特性的影响提供了一个很有前景的途径。
First Principles Simulations of Optical Rotation of Chiral Molecular Crystals
In this work, we present simulations of the optical rotation (OR) for five molecular crystals at density functional theory level with periodic boundary conditions (DFT-PBC). Calculations are compared with experimental measurements and show semi-quantitative agreement with experimental data for three of the crystals: tartatic acid, benzil, and pentaerythritol. For the other two crystals, aspartic acid and glutamic acid, the calculated data are in qualitative agreement with, but two orders of magnitude smaller than, the experimental data. We provide some arguments that support the theoretical predictions and suggest that the experiments should be revisited. We also find that the position of H centers provided in experimental X-ray data is not sufficiently reliable for simulating OR, and better results are obtained when H atoms are allowed to relax while keeping heavier elements fixed at the experimental positions. Comparison with molecular cluster calculations with a better functional and a larger basis set indicate that the role of intermolecular interactions (reproduced with the PBC technique) is as or more important than the choice of model chemistry. Despite the current limitations in the level of theory that can be employed, these simulations provide a promising avenue to investigate the effect of intermolecular interactions on this sensitive electronic property of molecules and materials.
期刊介绍:
The main aim of the journal is to publish original contributions of scientific work on the role of chirality in chemistry and biochemistry in respect to biological, chemical, materials, pharmacological, spectroscopic and physical properties.
Papers on the chemistry (physiochemical, preparative synthetic, and analytical), physics, pharmacology, clinical pharmacology, toxicology, and other biological aspects of chiral molecules will be published.