The findings highlight the presence of key intermediates in AOR (NH2, *NO, and *N) and underscore the critical role of the solvent in reaction kinetics. Analysis of kinetic parameters, such as activation energy and pre-exponential factor, revealed that the solvation kinetics of ions play a crucial role in AOR, much like in reactions such as HER and ORR, where hydroxide ion solvation-(de)solvation affects catalytic performance. Specifically, in AOR, the results distinguish between poisonous species (*N and *NO) that arise in parallel mechanisms at different potentials under time-dependent dynamic conditions.
Furthermore, the results show how these poisonous species influence the reaction’s activation energy and the configurational entropy of the catalyst surface. The catalytic activity of AOR also depends on the catalyst's surface charge, which varies with pH.
From a fundamental perspective, this work is pivotal for developing and designing new catalysts with high activity, stability, and selectivity, enabling the use of ammonia as an energy source in fuel cells or for synthesizing high-value chemical compounds.