Ground-State Long-Range Proton Transfer Controlled by Proton-Accepting Ability of Hydrogen-Bonded Chains: A Theoretical Study

IF 2.1 4区 化学 Q3 CHEMISTRY, PHYSICAL
H. Fang
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引用次数: 0

Abstract

The ground-state triple proton transfer (GSTPT) reactions in HCOOH complexing with H2O, CH3OH, C2H5OH and mixed water–alcohol molecules were studied by quantum mechanical methods in the gas phase and in heptane. The triple proton transfer in HCOOH–S1–S2 (S1, S2 = H2O, CH3OH, C2H5OH) systems all occurred in an asynchronous but concerted protolysis mechanism. The formation pattern of the hydrogen-bonded chain was important to reduce the barrier height of the proton transfer process. When the hydrogen-bonded chain consisted of two identical CH3OH or C2H5OH molecules in the HCOOH–S1–S2 complexes, the GSTPT barrier height of HCOOH–S1–S2 decreased by more than 2 kcal mol−1 compared to that of HCOOH–H2O–H2O both in the gas phase and in heptane, because CH3OH and C2H5OH had larger proton-accepting abilities than had H2O. When the two solvent molecules in the hydrogen-bonded chain in the HCOOH–S1–S2 complexes were different, the barrier height of the proton transfer process varied depending on the proton-accepting ability (basicity) of the hydrogen-bonded chain. The bigger the proton-accepting ability (basicity) of the hydrogen-bonded chain, the lower the barrier height of the proton transfer process. Mixed bridging solvent molecules could accumulate their proton-accepting abilities and thus speeded up proton transfer. The solvent effect evidently decreased the zero point energy-corrected barrier heights of HCOOH clusters and increased the asynchronicity of the proton transfer, while the proton transfer mechanisms did not change in heptane.
氢键链质子接受能力控制的基态远程质子转移的理论研究
用量子力学方法研究了HCOOH与H2O、CH3OH、C2H5OH和混合水-醇分子在气相和庚烷中的基态三质子转移(GSTPT)反应。HCOOH-S1-S2 (S1, S2 = H2O, CH3OH, C2H5OH)体系中的三重质子转移均发生在一个异步但协调的原水解机制中。氢键链的形成模式对降低质子转移过程的势垒高度具有重要意义。在HCOOH-S1-S2配合物中,当氢键链由两个相同的CH3OH或C2H5OH分子组成时,由于CH3OH和C2H5OH比H2O具有更大的质子接受能力,HCOOH-S1-S2的GSTPT势垒高度比hcooh - H2O在气相和正烷中的GSTPT势垒高度都降低了2 kcal mol−1以上。当HCOOH-S1-S2配合物中氢键链上的两种溶剂分子不同时,质子转移过程的势垒高度随氢键链的质子接受能力(碱度)的不同而变化。氢键链的质子接受能力(碱度)越大,质子转移过程的势垒高度越低。混合桥接溶剂分子可以积累质子接受能力,从而加速质子转移。溶剂效应明显降低了HCOOH簇的零点能修正势垒高度,增加了质子转移的不同步性,而质子转移机制在庚烷中没有改变。
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来源期刊
CiteScore
2.10
自引率
0.00%
发文量
5
审稿时长
2.3 months
期刊介绍: The journal covers the fields of kinetics and mechanisms of chemical processes in the gas phase and solution of both simple and complex systems.
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