Omer Kirshenboim scite author profile

Omer Kirshenboim

4Publications

93Citation Statements Received

446Citation Statements Given

How they've been cited

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255

436

Affiliations

Ben-Gurion University of the Negev

Publications

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How to Twist, Split and Warp a σ-Hole with Hypervalent Halogens

Kirshenboim

Kozuch

2016

J. Phys. Chem. A

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Halogen bonds (XB) are no longer newcomers in the chemistry family. However, XB in hypervalent halogens has not been thoroughly studied. We provide a molecular orbital explanation of the shape and strength of XBs in hypervalent halogens and other species, focusing on the charge transfer and electrostatic aspects of these bonds. Our results show that σ-holes (and subsequently the XBs associated with them) can be easily divided and bent by the influence of equatorial substituents. The inductive effect of both the equatorial and axial groups can affect these distortions, but also the angle between the equatorial ligands has a large influence on the shape of the σ-holes and the molecular orbitals acting as electron acceptor. Although the observation of these warped XB can be hindered by other noncovalent interactions, they may be ubiquitous in crystal structures of hypervalent species, where multiple XB can appear as secondary interactions on each halogen. We propose what can be considered the archetypal hypervalent halogen donor (a pincer type iodosodilactone) and a Lewis dot structure that includes the σ-holes.

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Switch chemistry at cryogenic conditions: quantum tunnelling under electric fields

2021

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Switch Chemistry at Cryogenic Conditions: Quantum Tunnelling under Electric Fields

Kirshenboim¹,

Frenklah²,

Kozuch³

2020

Preprint

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While the influence of intramolecular electric fields is a known feature in enzymes, the use of oriented external electric fields (EEF) to enhance or inhibit molecular reactivity is a promising topic still in its infancy. Herein we will explore computationally the effects that EEF can provoke in simple molecules close to the absolute zero, where quantum tunnelling (QT) is the sole mechanistic option. We studied three exemplary systems, each one with different reactivity features and known QT kinetics:  bond-shifting in pentalene, Cope rearrangement in semibullvalene, and cycloreversion of diazabicyclohexadiene. The kinetics of these cases depdend both on the field strength and its direction, usually giving subtle but remarkable changes. However, for the cycloreversion, which suffers large changes on the dipole through the reaction, we also observed striking results. Between the effects caused by the EEF on the QT we observed an inversion of the Arrhenius equation, deactivation of the molecular fluxionality, and stabilization or instantaneous decomposition of the system. All these effects may well be achieved, literally, at the flick of a switch.<br>

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Switch Chemistry at Cryogenic Conditions: Quantum Tunnelling under Electric Fields

Kirshenboim¹,

Frenklah²,

Kozuch³

2020

Preprint

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