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通过自适应力匹配和与实验参考值的适当比较,准确预测 20 种盐的水合自由能。

Accurate Prediction of the Hydration Free Energies of 20 Salts through Adaptive Force Matching and the Proper Comparison with Experimental References.

机构信息

Department of Chemistry and Biochemistry, University of Arkansas , Fayetteville, Arkansas 72701, United States.

出版信息

J Phys Chem B. 2017 Jul 13;121(27):6637-6645. doi: 10.1021/acs.jpcb.7b04618. Epub 2017 Jun 29.

DOI:10.1021/acs.jpcb.7b04618
PMID:28621540
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5665695/
Abstract

Simple pairwise potentials for five alkali ions and four halide ions were developed by only fitting to ab initio MP2 forces with the adaptive force matching (AFM) method. Without fitting to any experimental information, the AFM models predict the hydration free energies of all 10 fluoride and chloride salts formed by these ions within 1.5% of experimental references. The predicted hydration free energies for the 10 bromide and iodide salts are within 5-6% of experimental references with the larger error likely due to the neglect of explicit treatment of polarization and charge transfer. An inconsistency in the treatment of the gas phase entropy term between experimental and theoretical approaches is discussed. A new simplified hydration free energy for the ions is reported for use as a more appropriate experimental reference for further theoretical studies. The simulations show different dipole alignments for the hydration waters of cations and anions. While hydration waters of small cations tend to align their molecular dipole toward the ion, the dipole of one of the water OH bonds is aligned with the field of an anion.

摘要

仅通过拟合从头算 MP2 力的自适应力匹配 (AFM) 方法,为 5 种碱金属离子和 4 种卤化物离子开发了简单的成对势能。无需拟合任何实验信息,AFM 模型预测了由这些离子形成的所有 10 种氟化物和氯化物盐的水合自由能,与实验参考值的误差在 1.5%以内。对于 10 种溴化物和碘化物盐,预测的水合自由能与实验参考值的误差在 5-6%以内,较大的误差可能是由于忽略了对极化和电荷转移的显式处理。讨论了实验和理论方法在气相熵项处理方面的不一致性。报告了一种新的简化的离子水合自由能,用作进一步理论研究的更合适的实验参考。模拟结果表明,阳离子和阴离子的水合水分子的偶极取向不同。虽然小阳离子的水合水分子倾向于将其分子偶极朝向离子,但一个水分子的 OH 键的偶极与阴离子的场对齐。

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