Polarized Au(I)/Rh(I) Bimetallic Pairs Cooperatively Trigger Ligand Non-innocence and Bond Activation

Overview

Journal Dalton Trans

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2023 Mar 3

PMID 36866716

Authors

Macarena G Alferez

Juan J Moreno

Celia Maya

Jesus Campos

Affiliations

Soon will be listed here.

Abstract

The combination of molecular metallic fragments of contrasting Lewis character offers many possibilities for cooperative bond activation and for the disclosure of unusual reactivity. Here we provide a systematic investigation on the partnership of Lewis basic Rh(I) compounds of type [(η-L)Rh(PR)] (η-L = (CMe) or (CH)) with highly congested Lewis acidic Au(I) species. For the cyclopentadienyl Rh(I) compounds, we demonstrate the non-innocent role of the typically robust (CMe) ligand through migration of a hydride to the Rh site and provide evidence for the direct implication of the gold fragment in this unusual bimetallic ligand activation event. This process competes with the formation of dinuclear Lewis adducts defined by a dative Rh → Au bond, with selectivity being under kinetic control and tunable by modifying the stereoelectronic and chelating properties of the phosphine ligands bound to the two metals. We provide a thorough computational study on the unusual Cp* non-innocent behavior and the divergent bimetallic pathways observed. The cooperative FLP-type reactivity of all bimetallic pairs has been investigated and computationally examined for the case of N-H bond activation in ammonia.

Citing Articles

Ligand Postsynthetic Functionalization with Fluorinated Boranes and Implications in Hydrogenation Catalysis.

G Alferez M, Moreno J, Gaona M, Maya C, Campos J ACS Catal. 2024; 13(24):16055-16066.

PMID: 38344669 PMC: 10852356. DOI: 10.1021/acscatal.3c02764.

Cooperative activation of carbon-hydrogen bonds by heterobimetallic systems.

Lachguar A, Pichugov A, Neumann T, Dubrawski Z, Camp C Dalton Trans. 2023; 53(4):1393-1409.

PMID: 38126396 PMC: 10804807. DOI: 10.1039/d3dt03571a.

A Cavity-Shaped Gold(I) Fragment Enables CO Insertion into Au-OH and Au-NH Bonds.

Navarro M, Holzapfel M, Campos J Inorg Chem. 2023; 62(27):10582-10591.

PMID: 37367828 PMC: 10336967. DOI: 10.1021/acs.inorgchem.3c00751.

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