A Bis-(carbone) Pincer Ligand and Its Coordinative Behavior toward Multi-Metallic Configurations

Bamlaku Semagne Aweke; Cheng Han Yu; Minna Zhi; Wen Ching Chen; Glenn P.A. Yap; Lili Zhao; Tiow Gan Ong

doi:10.1002/anie.202201884

A Bis-(carbone) Pincer Ligand and Its Coordinative Behavior toward Multi-Metallic Configurations

Bamlaku Semagne Aweke, Cheng Han Yu, Minna Zhi, Wen Ching Chen, Glenn P.A. Yap, Lili Zhao, Tiow Gan Ong

School of Chemistry and Moleculai Engineering

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

16 Scopus citations

Abstract

Carbones are divalent carbon(0) species that contain two lone pairs of electrons. Herein, we have prepared the first known stable and isolable free bis-(carbone) pincer framework with a well-defined solid-state structure. This bis-(carbone) ligand is an effective scaffold for forming monometallic (Ni and Pd) and trinuclear heterometallic complexes with Au−Pd−Au, Au−Ni−Au, and Cu−Ni−Cu configurations. Sophisticated quantum-theoretical analyses found that the metal–metal interactions are too weak to play a significant role in upholding these multi-metallic configurations; rather, the four lone pairs of electrons within the bis-(carbone) framework are the main contributors to the stability of the complexes.

Original language	English
Article number	e202201884
Journal	Angewandte Chemie - International Edition
Volume	61
Issue number	24
DOIs	https://doi.org/10.1002/anie.202201884
State	Published - 13 Jun 2022

Keywords

Bis-(Carbone)
Heterometallic Coordination
Metal–Metal Interactions
Pincer Ligands

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10.1002/anie.202201884

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abstract = "Carbones are divalent carbon(0) species that contain two lone pairs of electrons. Herein, we have prepared the first known stable and isolable free bis-(carbone) pincer framework with a well-defined solid-state structure. This bis-(carbone) ligand is an effective scaffold for forming monometallic (Ni and Pd) and trinuclear heterometallic complexes with Au−Pd−Au, Au−Ni−Au, and Cu−Ni−Cu configurations. Sophisticated quantum-theoretical analyses found that the metal–metal interactions are too weak to play a significant role in upholding these multi-metallic configurations; rather, the four lone pairs of electrons within the bis-(carbone) framework are the main contributors to the stability of the complexes.",

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AU - Aweke, Bamlaku Semagne

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AU - Zhi, Minna

AU - Chen, Wen Ching

AU - Yap, Glenn P.A.

AU - Zhao, Lili

AU - Ong, Tiow Gan

PY - 2022/6/13

Y1 - 2022/6/13

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AB - Carbones are divalent carbon(0) species that contain two lone pairs of electrons. Herein, we have prepared the first known stable and isolable free bis-(carbone) pincer framework with a well-defined solid-state structure. This bis-(carbone) ligand is an effective scaffold for forming monometallic (Ni and Pd) and trinuclear heterometallic complexes with Au−Pd−Au, Au−Ni−Au, and Cu−Ni−Cu configurations. Sophisticated quantum-theoretical analyses found that the metal–metal interactions are too weak to play a significant role in upholding these multi-metallic configurations; rather, the four lone pairs of electrons within the bis-(carbone) framework are the main contributors to the stability of the complexes.

KW - Bis-(Carbone)

KW - Heterometallic Coordination

KW - Metal–Metal Interactions

KW - Pincer Ligands

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A Bis-(carbone) Pincer Ligand and Its Coordinative Behavior toward Multi-Metallic Configurations

Abstract

Keywords

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