Abstract
The realization of a hydrogen (H(2)) economy confronts formidable challenges in storage, transportation, and logistics. To address these challenges, H(2) carriers have been proposed as alternative solutions. Ammonia (NH(3)), as one of the most promising H(2) carriers, becomes a game-changer, offering higher volumetric H(2) density than compressed H(2), simplified logistics, and compatibility with existing infrastructure, which thereby reduces costs and supply chain complexities. However, fully realizing NH(3)'s potential requires overcoming downstream inefficiencies associated with its conversion either back into H(2) or into energy. Downstream processes primarily include thermal cracking, NH(3) electrolysis, and direct NH(3) fuel cells, two of which are electrochemical systems leveraging the NH(3) oxidation reaction (AOR). The efficiency of these electrochemical systems is significantly limited by severe surface poisoning and poor AOR catalytic activity, underscoring the urgent need for advanced catalyst design. Here, a comprehensive review of AOR electrocatalysis is provided, with a focus on mechanistic insights into activity-governing steps and surface poisoning pathways. Recent advances in catalyst design are summarized, and overlooked factors are highlighted for performance enhancement. Finally, perspectives on future research directions are presented for AOR catalyst development to accelerate the integration of NH(3)-based technologies into the hydrogen economy.