The origin of overpotential in lithium-mediated nitrogen reduction

Abstract: The verification of the lithium-mediated nitrogen reduction system in 2019 has led to an explosion in the literature focussing on improving the metrics of Faradaic efficiency, stability, and activity. However,...

“…In addition, this proof-of-concept can be applied to homemade coatings of LiFePO 4 commercial powders on metal wires that may be just as flexible as metal-based pseudoreference electrodes. , The second path is finding a way to directly correlate this measured potential to the reversible hydrogen electrode potential. Indeed, this reference potential is a standard both in aqueous and theoretical catalysis: knowing its relationship with measured potentials would enable quantification of the necessary electrochemical overpotential to drive the reaction, completing the picture given by the above analysis . In addition, H 2 oxidation is a likely counter electrode reaction for future N 2 reducing electrolyzers. , Therefore, it makes sense to measure voltage against that opposite reaction to have a more precise idea of the system’s energy efficiency.…”

“…Indeed, this reference potential is a standard both in aqueous and theoretical catalysis: knowing its relationship with measured potentials would enable quantification of the necessary electrochemical overpotential to drive the reaction, completing the picture given by the above analysis. 50 In addition, H 2 oxidation is a likely counter electrode reaction for future N 2 reducing electrolyzers. 38 , 39 Therefore, it makes sense to measure voltage against that opposite reaction to have a more precise idea of the system’s energy efficiency.…”

Nonaqueous Li-Mediated Nitrogen Reduction: Taking Control of Potentials

“…In addition, this proof-of-concept can be applied to homemade coatings of LiFePO 4 commercial powders on metal wires that may be just as flexible as metal-based pseudoreference electrodes. , The second path is finding a way to directly correlate this measured potential to the reversible hydrogen electrode potential. Indeed, this reference potential is a standard both in aqueous and theoretical catalysis: knowing its relationship with measured potentials would enable quantification of the necessary electrochemical overpotential to drive the reaction, completing the picture given by the above analysis . In addition, H 2 oxidation is a likely counter electrode reaction for future N 2 reducing electrolyzers. , Therefore, it makes sense to measure voltage against that opposite reaction to have a more precise idea of the system’s energy efficiency.…”

“…Indeed, this reference potential is a standard both in aqueous and theoretical catalysis: knowing its relationship with measured potentials would enable quantification of the necessary electrochemical overpotential to drive the reaction, completing the picture given by the above analysis. 50 In addition, H 2 oxidation is a likely counter electrode reaction for future N 2 reducing electrolyzers. 38 , 39 Therefore, it makes sense to measure voltage against that opposite reaction to have a more precise idea of the system’s energy efficiency.…”

Nonaqueous Li-Mediated Nitrogen Reduction: Taking Control of Potentials

“…Some reports propose that lithium nitride is directly protonated to ammonia, recycling the deposited lithium; ,, others propose that the layer of Li, or a mixed Li x N y H z layer, acts as an active surface for N 2 reduction. , In either case, nitrogen reduction must compete with hydrogen evolution and excessive lithium plating as parasitic side reactions; hence, there is a need to balance these competing reactions. Notably, the overpotentials for nitrogen reduction and hydrogen evolution are high due to the reaction operating at lithium-plating potential. ,,, …”

“…Notably, the overpotentials for nitrogen reduction and hydrogen evolution are high due to the reaction operating at lithiumplating potential. 4,6,10,11 We can understand lithium-mediated N 2 reduction by drawing insight from lithium-ion batteries: in both systems, a solid-electrolyte interphase (SEI) forms as a result of decomposition of electrolyte components at the highly reducing potentials. The SEI is an electrically insulating passivation layer which restricts further electrolyte degradation.…”

Water Increases the Faradaic Selectivity of Li-Mediated Nitrogen Reduction

“…In either case, nitrogen reduction must compete with hydrogen evolution and excessive lithium plating as parasitic side reactions, hence there is a need to balance these competing reactions. Notably, the overpotentials for nitrogen reduction and hydrogen evolution are high due to the reaction operating at lithium-plating potential 4,6,10,11 .…”

Water increases Faradaic selectivity of Li-mediated nitrogen reduction.