Iridium trihydride and tetrahydride complexes and their role in catalytic polarisation transfer from parahydrogen to pyruvate

Simon B. Duckett; Benjamin Tickner

doi:10.1039/d4sc06138a

Iridium trihydride and tetrahydride complexes and their role in catalytic polarisation transfer from parahydrogen to pyruvate

Simon B. Duckett, Benjamin Tickner

Chemistry

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

Abstract

This work details how the unusual iridium tetrahydride [Ir(H)4(IMes)(sulfoxide)]Na can be formed in a solvent dependent reaction of [IrCl(COD)(IMes)] with sulfoxide (dimethyl or methylphenyl), base, and H2. In the case of dimethyl sulfoxide, the four hydride ligands are equivalent, and the IMes and sulfoxide ligands mutually trans. However, for phenyl methyl sulfoxide, this isomer forms alongside its cis counterpart where the remarkable symmetry breaking effect of the sulfoxide leads to it presenting four chemically distinct hydride ligands. Subsequent reaction leads to their replacement with the corresponding trihydrides [Ir(H)3(IMes)(sulfoxide)2], where ligand chirality again plays a role in product selection. These products and their ligand arrangements are characterised and the reaction pathways leading to their formation probed using NMR spectroscopy and parahydrogen-hyperpolarised methods. Subsequently, they form as previously unidentified low concentration by-products in the important SABRE-catalysed hyperpolarisation of pyruvate, and their concentration should be minimised for efficient polarisation transfer.

Original language	English
Number of pages	9
Journal	Chemical Science
Early online date	12 Dec 2024
DOIs	https://doi.org/10.1039/d4sc06138a
Publication status	E-pub ahead of print - 12 Dec 2024

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10.1039/d4sc06138aLicence: CC BY

Iridium trihydride and tetrahydride complexes and their role in catalytic polarisation transfer from parahydrogen to pyruvate†
© 2024 The Author(s).
Final published version, 894 KBLicence: CC BY

Magnify: Creating the hyperpolarization battery to magnify NMR signals and improve analysis
Duckett, S. B. (Principal investigator)
EUROPEAN COMMISSION
1/01/23 → 31/12/27
Project: Research project (funded) › Research

Iridium trihydride and tetrahydride complexes and their role in catalytic polarisation transfer from parahydrogen to pyruvate
Duckett, S. B. (Creator) & Tickner, B. (Creator), University of York, 9 Dec 2024
DOI: 10.15124/fccecf8d-6d7d-4f76-85e0-7904413f86b5
Dataset

Cite this

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title = "Iridium trihydride and tetrahydride complexes and their role in catalytic polarisation transfer from parahydrogen to pyruvate",

abstract = "This work details how the unusual iridium tetrahydride [Ir(H)4(IMes)(sulfoxide)]Na can be formed in a solvent dependent reaction of [IrCl(COD)(IMes)] with sulfoxide (dimethyl or methylphenyl), base, and H2. In the case of dimethyl sulfoxide, the four hydride ligands are equivalent, and the IMes and sulfoxide ligands mutually trans. However, for phenyl methyl sulfoxide, this isomer forms alongside its cis counterpart where the remarkable symmetry breaking effect of the sulfoxide leads to it presenting four chemically distinct hydride ligands. Subsequent reaction leads to their replacement with the corresponding trihydrides [Ir(H)3(IMes)(sulfoxide)2], where ligand chirality again plays a role in product selection. These products and their ligand arrangements are characterised and the reaction pathways leading to their formation probed using NMR spectroscopy and parahydrogen-hyperpolarised methods. Subsequently, they form as previously unidentified low concentration by-products in the important SABRE-catalysed hyperpolarisation of pyruvate, and their concentration should be minimised for efficient polarisation transfer.",

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N2 - This work details how the unusual iridium tetrahydride [Ir(H)4(IMes)(sulfoxide)]Na can be formed in a solvent dependent reaction of [IrCl(COD)(IMes)] with sulfoxide (dimethyl or methylphenyl), base, and H2. In the case of dimethyl sulfoxide, the four hydride ligands are equivalent, and the IMes and sulfoxide ligands mutually trans. However, for phenyl methyl sulfoxide, this isomer forms alongside its cis counterpart where the remarkable symmetry breaking effect of the sulfoxide leads to it presenting four chemically distinct hydride ligands. Subsequent reaction leads to their replacement with the corresponding trihydrides [Ir(H)3(IMes)(sulfoxide)2], where ligand chirality again plays a role in product selection. These products and their ligand arrangements are characterised and the reaction pathways leading to their formation probed using NMR spectroscopy and parahydrogen-hyperpolarised methods. Subsequently, they form as previously unidentified low concentration by-products in the important SABRE-catalysed hyperpolarisation of pyruvate, and their concentration should be minimised for efficient polarisation transfer.

AB - This work details how the unusual iridium tetrahydride [Ir(H)4(IMes)(sulfoxide)]Na can be formed in a solvent dependent reaction of [IrCl(COD)(IMes)] with sulfoxide (dimethyl or methylphenyl), base, and H2. In the case of dimethyl sulfoxide, the four hydride ligands are equivalent, and the IMes and sulfoxide ligands mutually trans. However, for phenyl methyl sulfoxide, this isomer forms alongside its cis counterpart where the remarkable symmetry breaking effect of the sulfoxide leads to it presenting four chemically distinct hydride ligands. Subsequent reaction leads to their replacement with the corresponding trihydrides [Ir(H)3(IMes)(sulfoxide)2], where ligand chirality again plays a role in product selection. These products and their ligand arrangements are characterised and the reaction pathways leading to their formation probed using NMR spectroscopy and parahydrogen-hyperpolarised methods. Subsequently, they form as previously unidentified low concentration by-products in the important SABRE-catalysed hyperpolarisation of pyruvate, and their concentration should be minimised for efficient polarisation transfer.

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DO - 10.1039/d4sc06138a

M3 - Article

SN - 2041-6520

JO - Chemical Science

JF - Chemical Science

ER -

Iridium trihydride and tetrahydride complexes and their role in catalytic polarisation transfer from parahydrogen to pyruvate

Abstract

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Projects

Magnify: Creating the hyperpolarization battery to magnify NMR signals and improve analysis

Datasets

Iridium trihydride and tetrahydride complexes and their role in catalytic polarisation transfer from parahydrogen to pyruvate

Cite this