Cryogenic Rearrangements of Spiroheptadiyl: Light- or Heavy-Atom Quantum Tunneling?

Yuval Avivi; Juan Julian Santoyo-Flores; Tim Schleif; Sebastian Kozuch

doi:10.1021/acs.jpclett.4c02843

Cryogenic Rearrangements of Spiroheptadiyl: Light- or Heavy-Atom Quantum Tunneling?

Yuval Avivi, Juan Julian Santoyo-Flores, Tim Schleif, Sebastian Kozuch

Department of Chemistry

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

Abstract

Triplet 1,4-spiro[2.4]heptadiyl (SHD) has been shown experimentally to undergo rapid ring-opening and subsequent 1,2-hydrogen shift upon generation via photolysis of a diazene precursor at cryogenic temperatures. Modern computational tools elucidate the potential energy surface and kinetics behind this cascade reaction, disproving the earlier hypothesized mechanism invoking hot molecule effects in the first ring-opening step and tunneling in the second hydrogen transfer step. Instead, our results assign the SHD instability to heavy-atom tunneling and a subsequent photochemical hydrogen shift. This essentially is the opposite of the originally proposed mechanism. This case study thus addresses common misconceptions about the fundamental principles of tunneling involving hydrogen or carbon.

Original language	English
Pages (from-to)	163-167
Number of pages	5
Journal	Journal of Physical Chemistry Letters
DOIs	https://doi.org/10.1021/acs.jpclett.4c02843
State	Accepted/In press - 1 Jan 2024

ASJC Scopus subject areas

General Materials Science
Physical and Theoretical Chemistry

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10.1021/acs.jpclett.4c02843

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title = "Cryogenic Rearrangements of Spiroheptadiyl: Light- or Heavy-Atom Quantum Tunneling?",

abstract = "Triplet 1,4-spiro[2.4]heptadiyl (SHD) has been shown experimentally to undergo rapid ring-opening and subsequent 1,2-hydrogen shift upon generation via photolysis of a diazene precursor at cryogenic temperatures. Modern computational tools elucidate the potential energy surface and kinetics behind this cascade reaction, disproving the earlier hypothesized mechanism invoking hot molecule effects in the first ring-opening step and tunneling in the second hydrogen transfer step. Instead, our results assign the SHD instability to heavy-atom tunneling and a subsequent photochemical hydrogen shift. This essentially is the opposite of the originally proposed mechanism. This case study thus addresses common misconceptions about the fundamental principles of tunneling involving hydrogen or carbon.",

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AU - Schleif, Tim

AU - Kozuch, Sebastian

PY - 2024/1/1

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N2 - Triplet 1,4-spiro[2.4]heptadiyl (SHD) has been shown experimentally to undergo rapid ring-opening and subsequent 1,2-hydrogen shift upon generation via photolysis of a diazene precursor at cryogenic temperatures. Modern computational tools elucidate the potential energy surface and kinetics behind this cascade reaction, disproving the earlier hypothesized mechanism invoking hot molecule effects in the first ring-opening step and tunneling in the second hydrogen transfer step. Instead, our results assign the SHD instability to heavy-atom tunneling and a subsequent photochemical hydrogen shift. This essentially is the opposite of the originally proposed mechanism. This case study thus addresses common misconceptions about the fundamental principles of tunneling involving hydrogen or carbon.

AB - Triplet 1,4-spiro[2.4]heptadiyl (SHD) has been shown experimentally to undergo rapid ring-opening and subsequent 1,2-hydrogen shift upon generation via photolysis of a diazene precursor at cryogenic temperatures. Modern computational tools elucidate the potential energy surface and kinetics behind this cascade reaction, disproving the earlier hypothesized mechanism invoking hot molecule effects in the first ring-opening step and tunneling in the second hydrogen transfer step. Instead, our results assign the SHD instability to heavy-atom tunneling and a subsequent photochemical hydrogen shift. This essentially is the opposite of the originally proposed mechanism. This case study thus addresses common misconceptions about the fundamental principles of tunneling involving hydrogen or carbon.

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JO - Journal of Physical Chemistry Letters

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Cryogenic Rearrangements of Spiroheptadiyl: Light- or Heavy-Atom Quantum Tunneling?

Abstract

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