取代基在阳离子/π 相互作用和取代苯上方静电势中的影响主要归因于取代基的隔空效应。
Substituent effects in cation/pi interactions and electrostatic potentials above the centers of substituted benzenes are due primarily to through-space effects of the substituents.
机构信息
Department of Chemistry and Biochemistry, University of California, Los Angeles, California 90095, USA.
出版信息
J Am Chem Soc. 2009 Mar 11;131(9):3126-7. doi: 10.1021/ja809097r.
Abstract
Substituent effects in cation/pi interactions have been examined using the M05-2X DFT functional and CCSD(T) paired with triple-zeta-quality basis sets. In contrast to popular, intuitive models, trends in substituent effects are explained primarily in terms of direct through-space interactions with the substituents. While there is some scatter in the data, which is attributed to pi polarization, the trend in substituent effects in cation/pi interactions is captured by an additive model in which the substituent is isolated from the aryl ring. Similarly, changes in the electrostatic potential at a point above the center of a substituted benzene arise largely from through-space effects of the substituents; pi polarization is not the dominant underlying cause.
摘要
使用 M05-2X DFT 函数和 CCSD(T)与三重 zeta 质量基组研究了阳离子/π 相互作用中的取代基效应。与流行的直观模型相反,取代基效应的趋势主要用取代基与取代基的直接空间相互作用来解释。虽然数据中有一些分散,这归因于π极化,但阳离子/π 相互作用中取代基效应的趋势被一个加和模型所捕捉,其中取代基与芳环分离。同样,取代苯上方中心上方一点的静电势的变化主要来自取代基的空间效应;π 极化不是主要的潜在原因。
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