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Main Authors: Strasser, Nina, Sax, Alexander F.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.09399
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author Strasser, Nina
Sax, Alexander F.
author_facet Strasser, Nina
Sax, Alexander F.
contents The formation of the four three-ring systems \ce{c-(CH2)_{3-k}(SiH2)_{k}}, ($k=0$: cyclopropane, $k=1$: silirane, $k=2$: disilirane, $k=3$: cyclotrisilane) by addition of methylene and silylene to the double bond in ethene, disilene, and silaethene, as well as the elimination of the carbene analogs from the three-rings, was studied with CAS(4,4) wave functions in both $C_{2v}$ and $C_s$ symmetry. To reveal charge and spin redistribution during these reactions the CAS(4,4) wave functions were analyzed using the orthogonal valence bond method (OVB). The potential energy curves, different internal coordinates, and the results of the OVB analysis show, that frequently the addition and elimination reactions follow different minimum energy paths, because they are indeed diabatic reactions. In these cases, there are no energy barriers corresponding to saddle points on the potential energy surfaces but the energy increases during one diabatic reaction until, at a certain point, the system jumps to the other diabatic state and, in the following, the energy decreases. This happens for reactions in $C_{2v}$ symmetry; as soon as the system can change to the lower symmetry, the diabatic states combine to an adiabatic one and the reaction follows a single minimum energy path.
format Preprint
id arxiv_https___arxiv_org_abs_2411_09399
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Chemical bonding in three-membered ring systems
Strasser, Nina
Sax, Alexander F.
Chemical Physics
The formation of the four three-ring systems \ce{c-(CH2)_{3-k}(SiH2)_{k}}, ($k=0$: cyclopropane, $k=1$: silirane, $k=2$: disilirane, $k=3$: cyclotrisilane) by addition of methylene and silylene to the double bond in ethene, disilene, and silaethene, as well as the elimination of the carbene analogs from the three-rings, was studied with CAS(4,4) wave functions in both $C_{2v}$ and $C_s$ symmetry. To reveal charge and spin redistribution during these reactions the CAS(4,4) wave functions were analyzed using the orthogonal valence bond method (OVB). The potential energy curves, different internal coordinates, and the results of the OVB analysis show, that frequently the addition and elimination reactions follow different minimum energy paths, because they are indeed diabatic reactions. In these cases, there are no energy barriers corresponding to saddle points on the potential energy surfaces but the energy increases during one diabatic reaction until, at a certain point, the system jumps to the other diabatic state and, in the following, the energy decreases. This happens for reactions in $C_{2v}$ symmetry; as soon as the system can change to the lower symmetry, the diabatic states combine to an adiabatic one and the reaction follows a single minimum energy path.
title Chemical bonding in three-membered ring systems
topic Chemical Physics
url https://arxiv.org/abs/2411.09399