Photoreactivity of Deep VB Titania Attained Via Molecular Layer Deposition; Interplay of Metal Oxide Thin Film Built-in Strain and Molecular Effects

Keyphrases

• Molecular Effects 100%
• Strain Effect 100%
• Valence Band Maximum 100%
• Metal Oxide Thin Films 100%
• Molecular Layer Deposition 100%
• Photoactivity 100%
• Rutile 66%
• Photocatalytic Degradation 66%
• Benzoic Acid 66%
• Oxidation Potential 66%
• Charge Density 33%
• Porphyrin 33%
• Organic Molecules 33%
• Hydrogen Peroxide 33%
• Molecular Dipole 33%
• Oxide Materials 33%
• Organic-inorganic 33%
• Ionization Potential 33%
• Ethylene Glycol 33%
• Degradation Rate 33%
• Calcination 33%
• Promising Strategies 33%
• Photocatalytic 33%
• Photocatalysis 33%
• Oxides 33%
• Water Reservoir 33%
• Organic Removal 33%
• Calcination Process 33%
• Downshifting 33%
• Maximum Position 33%
• Thin-film Catalyst 33%
• Oxidative Potential 33%
• Molecular Charge 33%
• Degradation Reaction 33%
• Probe Molecule 33%
• Non-stoichiometric 33%
• Light Energy 33%
• Aromatic Carboxylic Acid 33%
• Photocatalytic Process 33%
• Photogenerated Holes 33%
• Photocatalytic Reactivity 33%
• Non-toxic Materials 33%
• Degradation Activity 33%
• Photocatalyses 33%

Chemical Engineering

• Molecular Layer 100%
• Film 100%
• Calcination 66%
• Photocatalytic Degradation 66%
• Organic Pollutant 33%
• Hydrogen Peroxide 33%
• Photocatalysis 33%
• Titanium Dioxide 33%
• Carboxylic Acid 33%
• Ethylene 33%
• Porphyrin 33%

Material Science

• Thin Films 100%
• Metal Oxide 100%
• Titanium Dioxide 100%
• Oxidation Reaction 40%
• Oxide Compound 40%
• Calcination 40%
• Density 20%
• Monolayers 20%
• Hydrogen Peroxide 20%
• Photocatalysis 20%
• Titanium 20%
• Optical Power 20%