2023
DOI: 10.1002/aenm.202203032
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Improving Electrocatalytic Nitrogen Reduction Selectivity and Yield by Suppressing Hydrogen Evolution Reaction via Electronic Metal–Support Interaction

Abstract: the H 2 precursor. This energy-intensive process reportedly costs ≈1.5% of the annual global energy consumption. [1,2] The electrocatalytic N 2 reduction reaction (NRR), which uses a renewable energy source and N 2 and H 2 O as the reactants, presents a highly promising strategy for NH 3 production under ambient conditions. [3][4][5][6][7] However, two aspects: poor catalytic activity and low selectivity of the electrocatalyst, significantly restrict the NRR process. First, the inert nitrogen with high cleavag… Show more

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Cited by 40 publications
(9 citation statements)
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“…At present, the development of NRR is still in its infancy stage and has encountered with several bottleneck issues. The FE (<60%), NH 3 partial current density ( j NH3 , < 1 mA cm –2 ), and NH 3 yield rate (at the level of 10 –9 mol s –1 cm –2 ) of NRR remain relatively low mainly due to the lack of efficient electrocatalysts. ,, Accordingly, developing efficient electrocatalysts and building the structure–activity relationship that can guide the design and optimization of electrocatalysts still should be the primarily tasks for the field. To achieve the goals, the advanced in situ spectroscopic techniques ( e.g.…”
Section: Conclusion and Future Outlookmentioning
confidence: 99%
“…At present, the development of NRR is still in its infancy stage and has encountered with several bottleneck issues. The FE (<60%), NH 3 partial current density ( j NH3 , < 1 mA cm –2 ), and NH 3 yield rate (at the level of 10 –9 mol s –1 cm –2 ) of NRR remain relatively low mainly due to the lack of efficient electrocatalysts. ,, Accordingly, developing efficient electrocatalysts and building the structure–activity relationship that can guide the design and optimization of electrocatalysts still should be the primarily tasks for the field. To achieve the goals, the advanced in situ spectroscopic techniques ( e.g.…”
Section: Conclusion and Future Outlookmentioning
confidence: 99%
“…The effect of electronic metal‐support interaction between metal Mo and VO 2 on NRR performance was evaluated (Figure 6c ), in which the electron‐defect‐rich Mo induced via electronic metal‐support interaction can effectively destabilize * N 2 and lower the energy barrier of the subsequent hydrogenation process. [ 85 ] Compared with VO 2 , the enhanced yield rate (10.8 times) and Faradic efficiency (2.8 times) were obtained by the addition of Mo. The ∆ G ( * N 2 ) − ∆ G ( * H) was chosen as the descriptor of NRR selectivity shown in Figure 6d,e , [ 86 ] where RuCu with more negative value (∆ G ( * N 2 ) − ∆ G ( * H)) achieved a higher Faradic efficiency compared with that of Ru.…”
Section: Progress Of Electrocatalyst Based On the Theory And Descriptorsmentioning
confidence: 99%
“…Reproduced with permission. [ 85 ] Copyright 2023, Wiley VCH. d) Schematic illustration of the synthesis of Ru–Cu nanoparticles.…”
Section: Progress Of Electrocatalyst Based On the Theory And Descriptorsmentioning
confidence: 99%
“…However, apart from the difficulty of nitrogen activation, the e-NRR in aqueous solution is limited by the competition of HER [ 42 ]. Several processes at the electrode–electrolyte interface occur concurrently, involving the diffusion and adsorption of reactant species, transfer of electrons and protons, as well as desorption of species, where e-NRR and HER share some reaction species for basically electro-hydrogenation reactions [ 43 , 44 ].…”
Section: Fundamental Comprehension On E-nrrmentioning
confidence: 99%