Electrostatic and Non-Electrostatic Contributions to Hydrogen Bonding and Proton Transfer in Solution Phase

IF 2.781

The Journal of Physical Chemistry Pub Date : 1996-12-12 DOI:10.1021/jp960555+

Patricia Pérez, Renato Contreras, Arie Aizman

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引用次数: 4

Abstract

A combined methodology of semiempirical density functional (DFT) and Hartree?Fock (HF) theories is used to analyze the solution-phase proton-transfer (PT) process in the H₂O···HX (X = F, Cl, and OH) model systems. Gas-phase PT, hydrogen bonding, ion-pairing, dissociation, and solvent effect are considered as the contributing factors to the solution PT reaction. The H-bonded and ion-pair structures are determined from the proton-transfer potential (PTP) profiles and full geometry optimization, using the Amsterdam density functional (ADF) code. These structures are then used as input to the semiempirical SCRF/CNDO method that incorporates solvent effects. The semiempirical SCRF gas-phase results qualitatively reproduce the experimental trend for the gas-phase proton affinities (PA) (OH^- > F^- > Cl^-). The solution-phase results correctly explain the strong acid character of HCl (pK_a < 0) and the weak dissociation of HF (pK_a > 0) in water.

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静电和非静电对溶液中氢键和质子转移的影响

半经验密度泛函(DFT)与Hartree?利用福克(HF)理论分析了H2O···HX (X = F、Cl和OH)模型体系的溶液相质子转移(PT)过程。气相PT、氢键、离子对、解离和溶剂效应是影响溶液PT反应的主要因素。利用阿姆斯特丹密度泛函(ADF)代码，从质子转移势(PTP)分布和全几何优化中确定了h键和离子对结构。然后将这些结构用作包含溶剂效应的半经验SCRF/CNDO方法的输入。半经验SCRF气相结果定性地再现了气相质子亲和(PA) (OH- >F -比;Cl -)。溶液相结果正确地解释了HCl (pKa <0)和HF (pKa >0)在水中。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Journal of Physical Chemistry

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