Electrocatalytic H₂ Evolution by Proton-Gated Hangman Iron Porphyrins

Abstract: The ability to control proton translocation is essential for optimizing electrocatalytic reductions in acidic solutions. We have synthesized a series of new hangman iron porphyrins with hanging groups of differing proton-donating abilities and evaluated their electrocatalytic hydrogen-evolving ability using foot-of-the-wave analysis. In the presence of excess triphenylphosphine, iron porphyrins initiate proton reduction electrocatalysis upon reduction to Fe I . By changing the proton-donating ability of the ha… Show more

“…While there only are a few examples of hydrogen evolution catalysts that have been studied using the FOWA analysis so far, 36,38 we believe that this report of catalytic Tafel behaviour will prove useful for future comparative purposes as more catalytic Tafel plots are reported.…”

Turning it off! Disfavouring hydrogen evolution to enhance selectivity for CO production during homogeneous CO₂ reduction by cobalt–terpyridine complexes

“…While there only are a few examples of hydrogen evolution catalysts that have been studied using the FOWA analysis so far, 36,38 we believe that this report of catalytic Tafel behaviour will prove useful for future comparative purposes as more catalytic Tafel plots are reported.…”

Turning it off! Disfavouring hydrogen evolution to enhance selectivity for CO production during homogeneous CO₂ reduction by cobalt–terpyridine complexes

“…355,356 Porphyrin-based transition metal complexes have been widely employed for the catalysis of energy-conversion-related small-molecule activation. 357 Many transition metal porphyrin complexes have been investigated as HECs, including Fe-, 358,359 Co-, 357,[360][361][362] and Ni-porphyrins. 363 The Fe-porphyrin complex 70 reported by Savéant and co-workers can produce H 2 from an acidic DMF solution at a TOF of 10 5 -10 6 s À1 .…”

Artificial photosynthesis: opportunities and challenges of molecular catalysts

“…Recent efforts have identified molecular metal complexes of Fe, Co, Ni, and Cu that are active for the HER. Nevertheless, despite these achievements, it is very rare to have one metal complex that can function as a molecular catalyst for hydrogen evolution with high efficiency and durability in aqueous solutions over a wide pH range.…”

Graphene‐Supported Pyrene‐Modified Cobalt Corrole with Axial Triphenylphosphine for Enhanced Hydrogen Evolution in pH 0–14 Aqueous Solutions