arXiv:2507.21121v1 Announce Type: new
Abstract: Electrochemical ammonia synthesis via lithium-mediated nitrogen dissociation has demonstrated exceptional Faradaic efficiency at ambient conditions, but its viability is limited by a high energy cost of ~9.12 eV per NH3 via lithium electrodeposition. Here, we establish the thermodynamic limits for dissociative nitrogen reduction using elemental metals by decomposing the process into three steps: metal deposition, nitridation, and protonation. We derive energetic constraints that any viable mediator must satisfy and show that highly reducing metals impose significant energetic penalties. To reduce this cost, we explore solvent tuning and bimetallic alloy strategies that shift deposition potentials without compromising nitridation spontaneity. Our results offer design principles for lowering the energy input of dissociative nitrogen reduction while maintaining its selectivity advantage over associative routes.