MoS₂ Nanoflowers Grown on Plasma-Induced W-Anchored Graphene for Efficient and Stable H₂ Production Through Seawater Electrolysis

Keyphrases

• Graphene 100%
• Molybdenite 100%
• H2 Production 100%
• Plasma-induced 100%
• Seawater Electrolysis 100%
• MoS2 Nanoflowers 100%
• Hydrogen Evolution Reaction 30%
• Seawater 20%
• Adsorption 10%
• Acidic Conditions 10%
• Weight Ratio 10%
• Nanosheets 10%
• Transition Metal Dichalcogenides 10%
• Sulfuric Acid 10%
• Gibbs Free Energy 10%
• Density Functional Calculations 10%
• Tungsten Oxide 10%
• Structure Model 10%
• Tafel Slope 10%
• H2 Dissociation 10%
• Graphene Nanosheets 10%
• 2D Transition Metal Dichalcogenides 10%
• Optimized Weights 10%
• Hydrogen Adsorption 10%
• Electrocatalytic Hydrogen Evolution 10%
• Alkaline Media 10%
• Alkaline Condition 10%
• Hydrogen Evolution Reaction Activity 10%
• Heterostructure Interface 10%
• Low Overpotential 10%
• Acidic Medium 10%
• Exchange Current Density 10%
• G-structure 10%
• Reaction Performance 10%
• DEC1 10%
• Faradaic Efficiency 10%
• 3d Transition Metal 10%
• Superior Catalyst 10%
• Rational Development 10%

Chemical Engineering

• Graphene 100%
• Nanoflower 100%
• H2 Production 100%
• Nanosheet 66%
• Transition Metal 66%
• Gibbs Free Energy 33%