Gas-phase preparation of silylacetylene (SiH3CCH) through a counterintuitive ethynyl radical (C2H) insertion

Shane J. Goettl; Allen Vincent; Mateus X. Silva; Zhenghai Yang; Breno R.L. Galvão; Rui Sun; Ralf I. Kaiser

doi:10.1126/sciadv.adq5018

Gas-phase preparation of silylacetylene (SiH₃CCH) through a counterintuitive ethynyl radical (C₂H) insertion

Shane J. Goettl, Allen Vincent, Mateus X. Silva, Zhenghai Yang, Breno R.L. Galvão^*, Rui Sun^*, Ralf I. Kaiser^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Elementary reaction mechanisms constitute a fundamental infrastructure for chemical processes as a whole. However, while these mechanisms are well understood for second-period elements, involving those of the third period and beyond can introduce unorthodox reactivity. Combining crossed molecular beam experiments with electronic structure calculations and molecular dynamics simulations, we provide compelling evidence on an exotic insertion of an unsaturated sigma doublet radical into a silicon-hydrogen bond as observed in the barrierless gas-phase reaction of the D1-ethynyl radical (C₂D) with silane (SiH₄). This pathway, which leads to the D1-silylacetylene (SiH₃CCD) product via atomic hydrogen loss, challenges the prerequisite and fundamental concept that two reactive electrons and an empty orbital are required for the open shell, unsaturated radical reactant to insert into a single bond.

Original language	English
Article number	eadq5018
Journal	Science Advances
Volume	10
Issue number	46
DOIs	https://doi.org/10.1126/sciadv.adq5018
State	Published - 15 Nov 2024
Externally published	Yes

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title = "Gas-phase preparation of silylacetylene (SiH3CCH) through a counterintuitive ethynyl radical (C2H) insertion",

abstract = "Elementary reaction mechanisms constitute a fundamental infrastructure for chemical processes as a whole. However, while these mechanisms are well understood for second-period elements, involving those of the third period and beyond can introduce unorthodox reactivity. Combining crossed molecular beam experiments with electronic structure calculations and molecular dynamics simulations, we provide compelling evidence on an exotic insertion of an unsaturated sigma doublet radical into a silicon-hydrogen bond as observed in the barrierless gas-phase reaction of the D1-ethynyl radical (C2D) with silane (SiH4). This pathway, which leads to the D1-silylacetylene (SiH3CCD) product via atomic hydrogen loss, challenges the prerequisite and fundamental concept that two reactive electrons and an empty orbital are required for the open shell, unsaturated radical reactant to insert into a single bond.",

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doi = "10.1126/sciadv.adq5018",

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AU - Goettl, Shane J.

AU - Vincent, Allen

AU - Silva, Mateus X.

AU - Yang, Zhenghai

AU - Galvão, Breno R.L.

AU - Sun, Rui

AU - Kaiser, Ralf I.

PY - 2024/11/15

Y1 - 2024/11/15

N2 - Elementary reaction mechanisms constitute a fundamental infrastructure for chemical processes as a whole. However, while these mechanisms are well understood for second-period elements, involving those of the third period and beyond can introduce unorthodox reactivity. Combining crossed molecular beam experiments with electronic structure calculations and molecular dynamics simulations, we provide compelling evidence on an exotic insertion of an unsaturated sigma doublet radical into a silicon-hydrogen bond as observed in the barrierless gas-phase reaction of the D1-ethynyl radical (C2D) with silane (SiH4). This pathway, which leads to the D1-silylacetylene (SiH3CCD) product via atomic hydrogen loss, challenges the prerequisite and fundamental concept that two reactive electrons and an empty orbital are required for the open shell, unsaturated radical reactant to insert into a single bond.

AB - Elementary reaction mechanisms constitute a fundamental infrastructure for chemical processes as a whole. However, while these mechanisms are well understood for second-period elements, involving those of the third period and beyond can introduce unorthodox reactivity. Combining crossed molecular beam experiments with electronic structure calculations and molecular dynamics simulations, we provide compelling evidence on an exotic insertion of an unsaturated sigma doublet radical into a silicon-hydrogen bond as observed in the barrierless gas-phase reaction of the D1-ethynyl radical (C2D) with silane (SiH4). This pathway, which leads to the D1-silylacetylene (SiH3CCD) product via atomic hydrogen loss, challenges the prerequisite and fundamental concept that two reactive electrons and an empty orbital are required for the open shell, unsaturated radical reactant to insert into a single bond.

UR - https://www.scopus.com/pages/publications/85209701871

U2 - 10.1126/sciadv.adq5018

DO - 10.1126/sciadv.adq5018

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Gas-phase preparation of silylacetylene (SiH₃CCH) through a counterintuitive ethynyl radical (C₂H) insertion

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