We report the first combined DFT and spectroscopic mechanistic investigation of a V(III)-chloride scorpionate complex, [VCl3{HC(pz)3}] (1), as a catalyst for the peroxidative oxidation of cyclohexane under mild conditions. DFT calculations reveal that 1 activates H2O2 through a multi-step oxidative mechanism following a V(III)→V (IV)→V(V) sequence, generating HOO⋅ radicals as the primary oxidizing species. The catalytic activity emerges from a competition between productive radical generation and self-trapping processes whose balance is governed by the H2O2/1 ratio, providing a molecular-level explanation for the experimentally observed trends in TON and alcohol/ketone selectivity. Unlike previously studied V(IV)/V(V) systems, the productive catalytic cycle follows a V(IV)→V(III)→V(IV) redox sequence, representing a novel mechanistic feature of vanadium-catalysed peroxidative oxidations. The proposed mechanism is validated experimentally by CW-EPR, pulsed ESEEM, and UV–Vis spectroscopy. These findings establish a clear optimization principle for V(III)-scorpionate catalysts in selective alkane oxidation under environmentally benign conditions.

Casella, G., Carlotto, S., Punis, R., Giulian, A.D., Bertani, R., Ribeiro, A.P.C., et al. (2026). Hydrogen peroxide activation by a C-scorpionate vanadium(III) catalyst for the peroxidative oxidation reaction of cyclohexane in mild conditions: A DFT and experimental study. MOLECULAR CATALYSIS, 600, 116049 [10.1016/j.mcat.2026.116049].

Hydrogen peroxide activation by a C-scorpionate vanadium(III) catalyst for the peroxidative oxidation reaction of cyclohexane in mild conditions: A DFT and experimental study

Casella, Girolamo
;
2026-07-01

Abstract

We report the first combined DFT and spectroscopic mechanistic investigation of a V(III)-chloride scorpionate complex, [VCl3{HC(pz)3}] (1), as a catalyst for the peroxidative oxidation of cyclohexane under mild conditions. DFT calculations reveal that 1 activates H2O2 through a multi-step oxidative mechanism following a V(III)→V (IV)→V(V) sequence, generating HOO⋅ radicals as the primary oxidizing species. The catalytic activity emerges from a competition between productive radical generation and self-trapping processes whose balance is governed by the H2O2/1 ratio, providing a molecular-level explanation for the experimentally observed trends in TON and alcohol/ketone selectivity. Unlike previously studied V(IV)/V(V) systems, the productive catalytic cycle follows a V(IV)→V(III)→V(IV) redox sequence, representing a novel mechanistic feature of vanadium-catalysed peroxidative oxidations. The proposed mechanism is validated experimentally by CW-EPR, pulsed ESEEM, and UV–Vis spectroscopy. These findings establish a clear optimization principle for V(III)-scorpionate catalysts in selective alkane oxidation under environmentally benign conditions.
lug-2026
Casella, G., Carlotto, S., Punis, R., Giulian, A.D., Bertani, R., Ribeiro, A.P.C., et al. (2026). Hydrogen peroxide activation by a C-scorpionate vanadium(III) catalyst for the peroxidative oxidation reaction of cyclohexane in mild conditions: A DFT and experimental study. MOLECULAR CATALYSIS, 600, 116049 [10.1016/j.mcat.2026.116049].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10447/706563
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