Computationally driven design of an artificial metalloenzyme using supramolecular anchoring strategies of iridium complexes to alcohol dehydrogenase

Abstract: Artificial metalloenzymes (ArMs) confer non-biological reactivities to biomolecules, whilst taking advantage of the biomolecular architecture in terms of selectivity and of renewable origin. In particular, ArMs design by supramolecular anchoring...

“…Where the I (A) is the value of the catalytic current (directly given by the electrochemical workstation), α is the number of transferred electrons corresponding to the half-reaction that generates a molecule of a target product or consumes a molecule of target reactant (the reaction equation Coefficient of electrons), N (mol) is the number of catalytically active sites, 94 and F (C/mol) is the Faraday constant. 95 …”

How to rationally design homogeneous catalysts for efficient CO2 electroreduction?

“…Where the I (A) is the value of the catalytic current (directly given by the electrochemical workstation), α is the number of transferred electrons corresponding to the half-reaction that generates a molecule of a target product or consumes a molecule of target reactant (the reaction equation Coefficient of electrons), N (mol) is the number of catalytically active sites, 94 and F (C/mol) is the Faraday constant. 95 …”

How to rationally design homogeneous catalysts for efficient CO2 electroreduction?

Artificial Metalloenzymes for Enantioselective Catalysis

Concluding remarks: discussion on natural and artificial enzymes including synthetic models