Keyphrases
Bismuth
100%
In Situ Formation
100%
Nickel Foam
100%
Bismuth Nanoparticles
100%
Electrocatalytic Nitrogen Reduction
100%
Ambient Ammonia Synthesis
100%
Nitrogen Reduction Reaction
75%
Ammonia Production
75%
Protonation
50%
Proton
50%
Electron Transfer
50%
Yield Rate
50%
Ammonia
50%
Production Performance
50%
Ammonia Yield
50%
Water Dissociation
50%
Conductive Substrate
25%
Faradaic Efficiency
25%
Strong Interaction
25%
Diffusion Layer
25%
Catalyst Layer
25%
Displacement Reaction
25%
Electrocatalyst
25%
Contact Resistance
25%
Energy Input
25%
Retention Rate
25%
Performance Investigation
25%
Cell Resistance
25%
Binder-free
25%
Nitrogen Dissociation
25%
H-type Cell
25%
Nickel Surfaces
25%
Integrated Electrode
25%
Polymer Binder
25%
Hydrogen Spillover
25%
Foam Electrode
25%
6-cycles
25%
Engineering
Protonation
100%
Mols
100%
Production Performance
100%
Situ Formation
100%
Ammonia Synthesis
100%
Nanoparticles
100%
Conductive
50%
Energy Input
50%
Catalyst Layer
50%
Strong Interaction
50%
Displacement Reaction
50%
Led Surface
50%
Diffusion Layer
50%
Polymer Binder
50%
Electrocatalysts
50%
Material Science
Nanoparticle
100%
Bismuth
100%
Surface (Surface Science)
33%
Electron Transfer
33%
Contact Resistance
16%
Electrocatalysts
16%
Chemical Engineering
Ammonia Synthesis
100%
Nanoparticle
100%
Nickel Nanoparticle
50%