The transition metal catalyzed [π2s + π2s + σ2s + σ2s] Pericyclic reaction: Woodward-hoffmann rules, aromaticity, and electron flow

Alexander Q. Cusumano; William A. Goddard; Brian M. Stoltz

doi:10.1021/jacs.0c09575

The transition metal catalyzed [π2s + π2s + σ2s + σ2s] Pericyclic reaction: Woodward-hoffmann rules, aromaticity, and electron flow

Alexander Q. Cusumano
, William A. Goddard
, Brian M. Stoltz

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

Abstract

We have shown that the fundamental step responsible for enantioinduction in the inner-sphere asymmetric Tsuji allylic alkylation is C-C bond formation through a seven-membered pericyclic transition state. We employ an extensive series of quantum mechanics (QM) calculations to delineate how the electronic structure of the Pd-catalyzed C-C bond forming process controls the reaction. Phase inversion introduced by d orbitals renders the Pd-catalyzed [π2s + π2s + σ2s + σ2s] reaction symmetry-allowed in the ground state, proceeding through a transition state with Craig-Möbius-like σ-aromaticity. Lastly, we connect QM to fundamental valence bonding concepts by deriving an ab initio "arrow-pushing"mechanism that describes the flow of electron density through the reaction.

Original language	English
Pages (from-to)	19033-19039
Number of pages	7
Journal	Journal of the American Chemical Society
Volume	142
Issue number	45
DOIs	https://doi.org/10.1021/jacs.0c09575
Publication status	Published - 11 Nov 2020
Externally published	Yes

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title = "The transition metal catalyzed [π2s + π2s + σ2s + σ2s] Pericyclic reaction: Woodward-hoffmann rules, aromaticity, and electron flow",

abstract = "We have shown that the fundamental step responsible for enantioinduction in the inner-sphere asymmetric Tsuji allylic alkylation is C-C bond formation through a seven-membered pericyclic transition state. We employ an extensive series of quantum mechanics (QM) calculations to delineate how the electronic structure of the Pd-catalyzed C-C bond forming process controls the reaction. Phase inversion introduced by d orbitals renders the Pd-catalyzed [π2s + π2s + σ2s + σ2s] reaction symmetry-allowed in the ground state, proceeding through a transition state with Craig-M{\"o}bius-like σ-aromaticity. Lastly, we connect QM to fundamental valence bonding concepts by deriving an ab initio {"}arrow-pushing{"}mechanism that describes the flow of electron density through the reaction.",

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AU - Goddard, William A.

AU - Stoltz, Brian M.

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PY - 2020/11/11

Y1 - 2020/11/11

N2 - We have shown that the fundamental step responsible for enantioinduction in the inner-sphere asymmetric Tsuji allylic alkylation is C-C bond formation through a seven-membered pericyclic transition state. We employ an extensive series of quantum mechanics (QM) calculations to delineate how the electronic structure of the Pd-catalyzed C-C bond forming process controls the reaction. Phase inversion introduced by d orbitals renders the Pd-catalyzed [π2s + π2s + σ2s + σ2s] reaction symmetry-allowed in the ground state, proceeding through a transition state with Craig-Möbius-like σ-aromaticity. Lastly, we connect QM to fundamental valence bonding concepts by deriving an ab initio "arrow-pushing"mechanism that describes the flow of electron density through the reaction.

AB - We have shown that the fundamental step responsible for enantioinduction in the inner-sphere asymmetric Tsuji allylic alkylation is C-C bond formation through a seven-membered pericyclic transition state. We employ an extensive series of quantum mechanics (QM) calculations to delineate how the electronic structure of the Pd-catalyzed C-C bond forming process controls the reaction. Phase inversion introduced by d orbitals renders the Pd-catalyzed [π2s + π2s + σ2s + σ2s] reaction symmetry-allowed in the ground state, proceeding through a transition state with Craig-Möbius-like σ-aromaticity. Lastly, we connect QM to fundamental valence bonding concepts by deriving an ab initio "arrow-pushing"mechanism that describes the flow of electron density through the reaction.

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ER -

The transition metal catalyzed [π2s + π2s + σ2s + σ2s] Pericyclic reaction: Woodward-hoffmann rules, aromaticity, and electron flow

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