Proton‐Coupled Electron Transfer from Hydrogen‐Bonded Phenols to Benzophenone Triplets

Riccardo Amorati; Luca Valgimigli; Caterina Viglianisi; Max Schmallegger; Dmytro Neshchadin; Georg Gescheidt-Demner

doi:10.1002/chem.201605931

Proton‐Coupled Electron Transfer from Hydrogen‐Bonded Phenols to Benzophenone Triplets

Riccardo Amorati^*, Luca Valgimigli, Caterina Viglianisi, Max Schmallegger, Dmytro Neshchadin^*, Georg Gescheidt-Demner

^*Corresponding author for this work

Institute of Physical and Theoretical Chemistry (6350)

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

Abstract

Phenols with intramolecular hydrogen bond between a pendant base and the phenolic OH group react differently in polar and non-polar environments with electron/proton acceptors. This was demonstrated by using time resolved chemically induced dynamic nuclear polarization (TR CIDNP) and theoretical calculations. In benzene, those phenols undergo a concerted electron–proton transfer (EPT) that yields neutral ketyl and phenoxyl radicals. In polar acetonitrile, the reaction mechanism turns into an electron transfer from the phenol to the triplet ketone, accompanied by the shift of a proton from the phenolic OH group to the nitrogen atom of the pendant base to form a distonic radical cation. This behavior is similar to that of tyrosine H-bonded to basic residues in some radical enzymes. This solvent-induced mechanism switch in proton-coupled electron transfers is important in different biological systems, in which the same metabolites and intermediates can react differently depending on the specific local environments

Original language	English
Pages (from-to)	5299-5306
Journal	Chemistry - a European Journal
Volume	23
Issue number	22
DOIs	https://doi.org/10.1002/chem.201605931
Publication status	Published - 24 Feb 2017

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title = "Proton‐Coupled Electron Transfer from Hydrogen‐Bonded Phenols to Benzophenone Triplets",

abstract = "Phenols with intramolecular hydrogen bond between a pendant base and the phenolic OH group react differently in polar and non-polar environments with electron/proton acceptors. This was demonstrated by using time resolved chemically induced dynamic nuclear polarization (TR CIDNP) and theoretical calculations. In benzene, those phenols undergo a concerted electron–proton transfer (EPT) that yields neutral ketyl and phenoxyl radicals. In polar acetonitrile, the reaction mechanism turns into an electron transfer from the phenol to the triplet ketone, accompanied by the shift of a proton from the phenolic OH group to the nitrogen atom of the pendant base to form a distonic radical cation. This behavior is similar to that of tyrosine H-bonded to basic residues in some radical enzymes. This solvent-induced mechanism switch in proton-coupled electron transfers is important in different biological systems, in which the same metabolites and intermediates can react differently depending on the specific local environments",

author = "Riccardo Amorati and Luca Valgimigli and Caterina Viglianisi and Max Schmallegger and Dmytro Neshchadin and Georg Gescheidt-Demner",

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TY - JOUR

T1 - Proton‐Coupled Electron Transfer from Hydrogen‐Bonded Phenols to Benzophenone Triplets

AU - Amorati, Riccardo

AU - Valgimigli, Luca

AU - Viglianisi, Caterina

AU - Schmallegger, Max

AU - Neshchadin, Dmytro

AU - Gescheidt-Demner, Georg

PY - 2017/2/24

Y1 - 2017/2/24

N2 - Phenols with intramolecular hydrogen bond between a pendant base and the phenolic OH group react differently in polar and non-polar environments with electron/proton acceptors. This was demonstrated by using time resolved chemically induced dynamic nuclear polarization (TR CIDNP) and theoretical calculations. In benzene, those phenols undergo a concerted electron–proton transfer (EPT) that yields neutral ketyl and phenoxyl radicals. In polar acetonitrile, the reaction mechanism turns into an electron transfer from the phenol to the triplet ketone, accompanied by the shift of a proton from the phenolic OH group to the nitrogen atom of the pendant base to form a distonic radical cation. This behavior is similar to that of tyrosine H-bonded to basic residues in some radical enzymes. This solvent-induced mechanism switch in proton-coupled electron transfers is important in different biological systems, in which the same metabolites and intermediates can react differently depending on the specific local environments

AB - Phenols with intramolecular hydrogen bond between a pendant base and the phenolic OH group react differently in polar and non-polar environments with electron/proton acceptors. This was demonstrated by using time resolved chemically induced dynamic nuclear polarization (TR CIDNP) and theoretical calculations. In benzene, those phenols undergo a concerted electron–proton transfer (EPT) that yields neutral ketyl and phenoxyl radicals. In polar acetonitrile, the reaction mechanism turns into an electron transfer from the phenol to the triplet ketone, accompanied by the shift of a proton from the phenolic OH group to the nitrogen atom of the pendant base to form a distonic radical cation. This behavior is similar to that of tyrosine H-bonded to basic residues in some radical enzymes. This solvent-induced mechanism switch in proton-coupled electron transfers is important in different biological systems, in which the same metabolites and intermediates can react differently depending on the specific local environments

U2 - 10.1002/chem.201605931

DO - 10.1002/chem.201605931

M3 - Article

SN - 0947-6539

VL - 23

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EP - 5306

JO - Chemistry - a European Journal

JF - Chemistry - a European Journal

IS - 22

ER -

Proton‐Coupled Electron Transfer from Hydrogen‐Bonded Phenols to Benzophenone Triplets

Abstract

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