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Understanding the Deactivation Pathways of Iridium(III) Pyridine‐Carboxiamide Catalysts for Formic Acid Dehydrogenation

Gabriel Menendez Rodriguez, Francesco Zaccaria, Leonardo Tensi, Cristiano Zuccaccia, Paola Belanzoni, Alceo Macchioni

2020Chemistry - A European Journal29 citationsDOI

Abstract

Abstract The degradation pathways of highly active [Cp*Ir(κ 2 ‐ N , N ‐R‐pica)Cl] catalysts (pica=picolinamidate; 1 R=H, 2 R=Me) for formic acid (FA) dehydrogenation were investigated by NMR spectroscopy and DFT calculations. Under acidic conditions (1 equiv. of HNO 3 ), 2 undergoes partial protonation of the amide moiety, inducing rapid κ 2 ‐ N , N to κ 2 ‐ N , O ligand isomerization. Consistently, DFT modeling on the simpler complex 1 showed that the κ 2 ‐ N , N key intermediate of FA dehydrogenation ( I NH ), bearing a N ‐protonated pica, can easily transform into the κ 2 ‐ N , O analogue ( I NH2 ; Δ G ≠ ≈11 kcal mol −1 , Δ G ≈−5 kcal mol −1 ). Intramolecular hydrogen liberation from I NH2 is predicted to be rather prohibitive (Δ G ≠ ≈26 kcal mol −1 , Δ G ≈23 kcal mol −1 ), indicating that FA dehydrogenation should involve mostly κ 2 ‐ N , N intermediates, at least at relatively high pH. Under FA dehydrogenation conditions, 2 was progressively consumed, and the vast majority of the Ir centers (58 %) were eventually found in the form of Cp*‐complexes with a pyridine‐amine ligand. This likely derived from hydrogenation of the pyridine‐carboxiamide via a hemiaminal intermediate, which could also be detected. Clear evidence for ligand hydrogenation being the main degradation pathway also for 1 was obtained, as further confirmed by spectroscopic and catalytic tests on the independently synthesized degradation product 1 c . DFT calculations confirmed that this side reaction is kinetically and thermodynamically accessible.

Topics & Concepts

DehydrogenationChemistryProtonationPyridineMedicinal chemistryCatalysisFormic acidLigand (biochemistry)IsomerizationIntramolecular forceHexacoordinateAmideMoietyPhotochemistryStereochemistryOrganic chemistryIonBiochemistrySiliconReceptorCarbon dioxide utilization in catalysisCO2 Reduction Techniques and CatalystsAsymmetric Hydrogenation and Catalysis