Investigating the formation of metal nitride complexes employing a tetradentate bis-carbene bis-phenolate ligand

Abstract

The synthesis of MnV and CrV nitride complexes of a pro-radical tetradentate bis-phenol bis-N-heterocyclic carbene ligand H2LC2O2 was investigated. Employing either azide photolysis of the MnIII precursor complex MnLC2O2(N3) or a nitride exchange reaction between MnLC2O2(Br) and the nitride exchange reagent Mnsalen(N) failed to provide a useful route to the target nitride MnLC2O2(N). Experimental results support initial formation of the target nitride MnLC2O2(N), however, the nitride rapidly inserts into a Mn–CNHC bond. A second insertion reaction results in the isolation of the doubly inserted ligand product [H2LC2O2(N)]+ in good yield. In contrast, the Cr analogue CrLC2O2(N) was readily prepared and characterized by a number of experimental methods, including X-ray crystallography. Theoretical calculations predict a lower transition state energy for nitride insertion into the M–CNHC bond for Mn in comparison to Cr, and in addition the N-inserted product is stabilized for Mn while destabilized for Cr. Natural bond order (NBO) analysis predicts that the major bonding interaction (π M[triple bond, length as m-dash]N → σ* M–CNHC) promotes nucleophilic attack of the nitride on the carbene as the major reaction pathway. Finally, one-electron oxidation of CrLC2O2(N) affords a relatively stable cation that is characterized by experimental and theoretical analysis to be a metal-oxidized d0 CrVI species.

Graphical abstract: Investigating the formation of metal nitride complexes employing a tetradentate bis-carbene bis-phenolate ligand

Supplementary files

Article information

Article type
Paper
Submitted
17 Jūn. 2024
Accepted
01 Nov. 2024
First published
08 Nov. 2024

Dalton Trans., 2025, Advance Article

Investigating the formation of metal nitride complexes employing a tetradentate bis-carbene bis-phenolate ligand

R. Kunert, D. Martelino, S. Mahato, N. M. Hein, J. Pulfer, C. Philouze, O. Jarjayes, F. Thomas and T. Storr, Dalton Trans., 2025, Advance Article , DOI: 10.1039/D4DT01765J

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