Ping-pong tunneling reactions, part 2: Boron and carbon bell-clapper rearrangement

Ashim Nandi; Adam Sucher; Anat Tyomkin; Sebastian Kozuch

doi:10.1515/pac-2019-0401

Ping-pong tunneling reactions, part 2: Boron and carbon bell-clapper rearrangement

Ashim Nandi, Adam Sucher, Anat Tyomkin, Sebastian Kozuch

Department of Chemistry

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

10 Scopus citations

Abstract

Anthracene can be used as a scaffold for intramolecular S_N2 degenerate reactions of the "bell clapper" type, where a central boron atom or its isoelectronic carbocation bonds alternatively towards one or the other lateral Lewis bases at the first and eight anthracene positions. This ping-pong bond-switching reaction possesses a symmetrical double-well potential with low activation barrier and relatively narrow barrier width. Herein we show by computational means the active role played by heavy atom quantum tunneling in this degenerate rearrangement reaction at cryogenic temperatures. At these conditions the thermal "over the barrier" reaction is forbidden, whereas the tunneling effect enhances the rate of reaction up to an experimentally measurable half-life. Kinetic isotope effects and cryogenic NMR spectroscopy can, in principle, experimentally demonstrate the tunneling mechanism.

Original language	English
Pages (from-to)	39-47
Number of pages	9
Journal	Pure and Applied Chemistry
Volume	92
Issue number	1
DOIs	https://doi.org/10.1515/pac-2019-0401
State	Published - 1 Jan 2020

Keywords

ICPOC-24
NMR
bell-clapper reaction
boron
computational chemistry
kinetic isotope effect
kinetics
quantum tunneling

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering

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abstract = "Anthracene can be used as a scaffold for intramolecular SN2 degenerate reactions of the {"}bell clapper{"} type, where a central boron atom or its isoelectronic carbocation bonds alternatively towards one or the other lateral Lewis bases at the first and eight anthracene positions. This ping-pong bond-switching reaction possesses a symmetrical double-well potential with low activation barrier and relatively narrow barrier width. Herein we show by computational means the active role played by heavy atom quantum tunneling in this degenerate rearrangement reaction at cryogenic temperatures. At these conditions the thermal {"}over the barrier{"} reaction is forbidden, whereas the tunneling effect enhances the rate of reaction up to an experimentally measurable half-life. Kinetic isotope effects and cryogenic NMR spectroscopy can, in principle, experimentally demonstrate the tunneling mechanism.",

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AU - Nandi, Ashim

AU - Sucher, Adam

AU - Tyomkin, Anat

AU - Kozuch, Sebastian

PY - 2020/1/1

Y1 - 2020/1/1

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AB - Anthracene can be used as a scaffold for intramolecular SN2 degenerate reactions of the "bell clapper" type, where a central boron atom or its isoelectronic carbocation bonds alternatively towards one or the other lateral Lewis bases at the first and eight anthracene positions. This ping-pong bond-switching reaction possesses a symmetrical double-well potential with low activation barrier and relatively narrow barrier width. Herein we show by computational means the active role played by heavy atom quantum tunneling in this degenerate rearrangement reaction at cryogenic temperatures. At these conditions the thermal "over the barrier" reaction is forbidden, whereas the tunneling effect enhances the rate of reaction up to an experimentally measurable half-life. Kinetic isotope effects and cryogenic NMR spectroscopy can, in principle, experimentally demonstrate the tunneling mechanism.

KW - ICPOC-24

KW - NMR

KW - bell-clapper reaction

KW - boron

KW - computational chemistry

KW - kinetic isotope effect

KW - kinetics

KW - quantum tunneling

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JO - Pure and Applied Chemistry

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Ping-pong tunneling reactions, part 2: Boron and carbon bell-clapper rearrangement

Abstract

Keywords

ASJC Scopus subject areas

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