Protic NHC Iridium Complexes with β-H Reactivity–Synthesis, Acetonitrile Insertion, and Oxidative Self-Activation

Mark K. Rong; Andrei Chirila; David Franciolus; Martin Lutz; Martin Nieger; Andreas W. Ehlers; J. Chris Slootweg; Koop Lammertsma

doi:10.1021/acs.organomet.9b00584

Protic NHC Iridium Complexes with β-H Reactivity–Synthesis, Acetonitrile Insertion, and Oxidative Self-Activation

Mark K. Rong, Andrei Chirila, David Franciolus, Martin Lutz, Martin Nieger, Andreas W. Ehlers, J. Chris Slootweg, Koop Lammertsma

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

Abstract

Protic NHC iridium complexes, obtained from the corresponding azido-phenylene-isocyanide precursor complexes, were investigated for ligand-based reactivity. Under redox-neutral conditions, acetonitrile inserts into the N–H bonds to provide κ2-NHC-imidoyl ligand-based complexes, while under reductive conditions the complex also expels one N–H proton to provide the corresponding deprotonated analogues. Using zinc as a reductor activates the NHC-iridium complex to form an asymmetric bimetallic iridium hydrido complex, in which two anionic N-deprotonated NHCs bridge the bimetallic core. X-ray crystal structures are reported for the azido-phenylene-isocyanide precursor complex, the protic NHC complex, and the asymmetric bimetallic iridium hydride complex. Density functional computations and a QTAIM analysis of the bimetallic iridium hydrido complex are provided.

Original language	English
Pages (from-to)	4543-4553
Journal	Organometallics
Volume	38
Issue number	23
DOIs	https://doi.org/10.1021/acs.organomet.9b00584
Publication status	Published - 9 Dec 2019

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@article{9d75fbf5891449ca8285d44301c7739e,

title = "Protic NHC Iridium Complexes with β-H Reactivity–Synthesis, Acetonitrile Insertion, and Oxidative Self-Activation",

abstract = "Protic NHC iridium complexes, obtained from the corresponding azido-phenylene-isocyanide precursor complexes, were investigated for ligand-based reactivity. Under redox-neutral conditions, acetonitrile inserts into the N–H bonds to provide κ2-NHC-imidoyl ligand-based complexes, while under reductive conditions the complex also expels one N–H proton to provide the corresponding deprotonated analogues. Using zinc as a reductor activates the NHC-iridium complex to form an asymmetric bimetallic iridium hydrido complex, in which two anionic N-deprotonated NHCs bridge the bimetallic core. X-ray crystal structures are reported for the azido-phenylene-isocyanide precursor complex, the protic NHC complex, and the asymmetric bimetallic iridium hydride complex. Density functional computations and a QTAIM analysis of the bimetallic iridium hydrido complex are provided.",

author = "Rong, \{Mark K.\} and Andrei Chirila and David Franciolus and Martin Lutz and Martin Nieger and Ehlers, \{Andreas W.\} and Slootweg, \{J. Chris\} and Koop Lammertsma",

year = "2019",

month = dec,

day = "9",

doi = "10.1021/acs.organomet.9b00584",

language = "English",

volume = "38",

pages = "4543--4553",

journal = "Organometallics",

issn = "0276-7333",

publisher = "American Chemical Society",

number = "23",

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TY - JOUR

T1 - Protic NHC Iridium Complexes with β-H Reactivity–Synthesis, Acetonitrile Insertion, and Oxidative Self-Activation

AU - Rong, Mark K.

AU - Chirila, Andrei

AU - Franciolus, David

AU - Lutz, Martin

AU - Nieger, Martin

AU - Ehlers, Andreas W.

AU - Slootweg, J. Chris

AU - Lammertsma, Koop

PY - 2019/12/9

Y1 - 2019/12/9

N2 - Protic NHC iridium complexes, obtained from the corresponding azido-phenylene-isocyanide precursor complexes, were investigated for ligand-based reactivity. Under redox-neutral conditions, acetonitrile inserts into the N–H bonds to provide κ2-NHC-imidoyl ligand-based complexes, while under reductive conditions the complex also expels one N–H proton to provide the corresponding deprotonated analogues. Using zinc as a reductor activates the NHC-iridium complex to form an asymmetric bimetallic iridium hydrido complex, in which two anionic N-deprotonated NHCs bridge the bimetallic core. X-ray crystal structures are reported for the azido-phenylene-isocyanide precursor complex, the protic NHC complex, and the asymmetric bimetallic iridium hydride complex. Density functional computations and a QTAIM analysis of the bimetallic iridium hydrido complex are provided.

AB - Protic NHC iridium complexes, obtained from the corresponding azido-phenylene-isocyanide precursor complexes, were investigated for ligand-based reactivity. Under redox-neutral conditions, acetonitrile inserts into the N–H bonds to provide κ2-NHC-imidoyl ligand-based complexes, while under reductive conditions the complex also expels one N–H proton to provide the corresponding deprotonated analogues. Using zinc as a reductor activates the NHC-iridium complex to form an asymmetric bimetallic iridium hydrido complex, in which two anionic N-deprotonated NHCs bridge the bimetallic core. X-ray crystal structures are reported for the azido-phenylene-isocyanide precursor complex, the protic NHC complex, and the asymmetric bimetallic iridium hydride complex. Density functional computations and a QTAIM analysis of the bimetallic iridium hydrido complex are provided.

U2 - 10.1021/acs.organomet.9b00584

DO - 10.1021/acs.organomet.9b00584

M3 - Article

SN - 0276-7333

VL - 38

SP - 4543

EP - 4553

JO - Organometallics

JF - Organometallics

IS - 23

ER -

Protic NHC Iridium Complexes with β-H Reactivity–Synthesis, Acetonitrile Insertion, and Oxidative Self-Activation

Abstract

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