Molecular Conjugated‐Polymer Electrode Enables Rapid Proton Conduction for Electrosynthesis of Ammonia from Nitrate
Xinhao Su, Feiyang Hong, Yanjie Fang, Yingke Wen, Bing Shan
Abstract
Abstract Electrosynthesis of ammonia (NH 3 ) from nitrate (NO 3 − ) using renewable energy holds promise as a supplementary alternative to the Haber−Bosch process for NH 3 production. Most research focuses on tuning the catalytic activity of metal catalysts by modification of the catalyst structures. However, the electrode supports which could influence the catalytic activity have not been well‐explored. The state‐of‐the‐art electrocatalysts for NO 3 − reduction to NH 3 still exhibit limited energy efficiency at ampere‐level current density. Herein, we report a polyaniline‐based molecular electrode with Cu catalyst for selective and energy‐efficient NO 3 − reduction to NH 3 . In the electrode, the polyaniline promotes protonation of the key intermediate formed during NO 3 − reduction at Cu, which circumvents the limitation of the Cu catalyst in the efficiency‐limiting proton transfer step. The molecular electrode produces NH 3 at a partial current density of 2.7 A cm −2 with an energy efficiency of 62 %, demonstrating much better electrochemical performance than common Cu‐based electrocatalysts and indicating the great potential in molecular engineering of electrode supports for selective NO 3 − reduction.