Pendant Proton‐Relays Systematically Tune the Rate and Selectivity of Electrocatalytic Ammonia Generation in a Fe‐Porphyrin Based Metal–Organic Framework

Electrocatalytic nitrite reduction (eNO2RR) is a promising alternative route to produce ammonia (NH3). Until now, several molecular catalysts have shown capability to homogeneously reduce nitrite to NH3, while taking advantage of added secondary‐sphere functionalities to direct catalytic performance...

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Veröffentlicht in:Angewandte Chemie 2024-09, Vol.136 (37), p.n/a
Hauptverfasser: Ghatak, Arnab, Shanker, G. Shiva, Sappati, Subrahmanyam, Liberman, Itamar, Shimoni, Ran, Hod, Idan
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Sprache:eng
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Zusammenfassung:Electrocatalytic nitrite reduction (eNO2RR) is a promising alternative route to produce ammonia (NH3). Until now, several molecular catalysts have shown capability to homogeneously reduce nitrite to NH3, while taking advantage of added secondary‐sphere functionalities to direct catalytic performance. Yet, realizing such control over heterogeneous electrocatalytic surfaces remains a challenge. Herein, we demonstrate that heterogenization of a Fe‐porphyrin molecular catalyst within a 2D Metal–Organic Framework (MOF), allows efficient eNO2RR to NH3. On top of that, installation of pendant proton relaying moieties proximal to the catalytic site, resulted in significant improvement in catalytic activity and selectivity. Notably, systematic manipulation of NH3 faradaic efficiency (up to 90 %) and partial current (5‐fold increase) was achieved by varying the proton relay‐to‐catalyst molar ratio. Electrochemical and spectroscopic analysis show that the proton relays simultaneously aid in generating and stabilizing of reactive Fe‐bound NO intermediate. Thus, this concept offers new molecular tools to tune heterogeneous electrocatalytic systems. Installation of secondary sphere proton relaying functionalities within an iron‐porphyrin based MOF, enables systematic adjustment of heterogeneous electrocatalytic nitrite reduction performance in aqueous solution. Thus, high rates of NH3 production at more than 90 % faradaic efficiency were obtained.
ISSN:0044-8249
1521-3757
DOI:10.1002/ange.202407667