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Abstract
Ammonia (NH3) is a promising carbon-free fuel when prepared from sustainable resources. First-row transition metal electrocatalysts for ammonia oxidation are an enabling technology for sustainable energy production. We describe electrocatalytic ammonia oxidation using robust molecular complexes based on Earth-abundant iron. Electrochemical studies of ferrocenes with covalently attached pyridine arms reveal facile ammonia oxidation in DMSO (2.4 M NH3) with modest overpotentials (770 - 820 mV) and turnover frequencies (125 - 560 h-1). Experimental and compu-tational studies indicate that the pendant pyridyl base serves as an H-bond acceptor with an N-H bond of ammonia that transfers a proton to the pyridine following oxidation by the attached ferrocenium moiety in a proton-coupled electron transfer (PCET) step. This generates an amidyl (•NH2) radical stabilized via H-bonding to a pendant pyri-dinium moiety that rapidly dimerizes to hydrazine (H2NNH2), which is easily oxidized to nitrogen (N2) at the glassy carbon working electrode. This report identifies a general strategy to oxidize ammonia via H-bonding to a base (B:), thereby activating [B…H-NH2] towards PCET by a proximal oxidant to form [BH…NH2]+/• radical cations, which are sus-ceptible to dimerization to form easily oxidized hydrazine.
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