Ab initio molecular orbital calculations on the interconversion of allene and propyne cation radicals and the mechanism for hydrogen loss from C3H4+·

International Journal of Mass Spectrometry and Ion Physics Pub Date : 1983-09-01 DOI:10.1016/0020-7381(83)85034-7

Gernot Frenking, Helmut Schwarz

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引用次数: 29

Abstract

Ab initio molecular orbital calculations (6-31G*/MNDO) of the C₃H₄^+· potential energy surface (electronic ground state) reveal the following features. The molecular ions of allene (1) and propyne (2) are separated by substantial potential energy barriers which preclude easy interconversion. The minimal energy requirement path for the 1 ⇌ 2 isomerization proceeds via two successive 1,2-hydrogen migrations and involves the as yet unknown stable, linear C₃H₄^+· ion 5. Isomerization via a direct 1,3-hydrogen migration is, if it is involved at all, energetically less favoured. The ion 5 also serves as the central intermediate for ring closure to the cation radical of cyclopropene (4), which itself is the actual precursor for loss of H^· thus generating the cyclopropenylium ion (3). The complete geometric data of the various C₃H₄^+· isomers and the transition states connecting them are reported.

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丙烯和丙烯阳离子自由基相互转化的从头算分子轨道计算及C3H4+·氢损失机理

从头算C3H4+·势能面(电子基态)的分子轨道计算(6-31G*/MNDO)揭示了以下特征:烯(1)和丙烯(2)的分子离子被大量的势能势垒隔开，阻碍了容易的相互转化。1 + 2异构化的最小能量需求途径是通过两个连续的1,2-氢迁移进行的，并且涉及到目前未知的稳定的线性C3H4+·离子5。通过1,3-氢的直接迁移进行的异构化，如果有的话，在能量上是不太有利的。离子5也是环丙烯(4)阳离子自由基的中心中间体，它本身是H·损失的实际前体，从而产生环丙烯离子(3)。报道了各种C3H4+·异构体的完整几何数据和连接它们的过渡态。

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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International Journal of Mass Spectrometry and Ion Physics

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