Titanate nanotubes sensitized with silver nanoparticles: synthesis, characterization and in-situ pollutants photodegradation

Keyphrases

• In Situ 100%
• Nanotube Surface 100%
• Ag Nanoparticles (AgNPs) 100%
• Ag + 100%
• Silver Nanoparticles Synthesis 100%
• Pollutant Photodegradation 100%
• Titanate Nanotubes 100%
• Phenol Solution 100%
• Nanocomposite Materials 100%
• UV-VIS Spectroscopy 50%
• Morphological Characterization 50%
• Structural Characterization 50%
• X-ray Powder Diffraction 50%
• Exchange Processes 50%
• X-ray Photoelectron Spectroscopy 50%
• Silver Nanoparticles 50%
• Diffuse Reflectance Spectroscopy 50%
• Transmission Electron Microscopy 50%
• Reusability 50%
• Nanotubes 50%
• External Surface 50%
• Nanotube Morphology 50%
• Irradiation Time 50%
• Characterization Results 50%
• Photochemical Stability 50%
• Micro X-ray Fluorescence 50%
• Pollutant Degradation 50%
• Photocatalyst 50%
• Photodegradation Efficiency 50%
• Photocatalytic Degradation 50%
• Photocatalytic Activity 50%
• Enhanced Photocatalytic Activity 50%
• Continuous Growth 50%
• Catalytic Photodegradation 50%
• Terephthalic Acid 50%
• Phenol Degradation 50%
• Hydrothermal Approach 50%
• Metallic Ag Nanoparticles 50%
• Degradation Test 50%
• Phenol Removal 50%
• Interlayer Spacing 50%
• Nanocomposite Samples 50%
• Hydroxyl Radical Generation 50%
• Catalytic Reusability 50%

Material Science

• Silver Nanoparticle 100%
• Nanotube 100%
• Photodegradation 100%
• Nanoparticle Synthesis 100%
• Titanate Nanotube 100%
• Surface (Surface Science) 75%
• Nanocomposite 75%
• Nanoparticle 75%
• Morphology 50%
• X Ray Powder Diffraction 25%
• X-Ray Photoelectron Spectroscopy 25%
• Transmission Electron Microscopy 25%
• X-Ray Fluorescence Spectroscopy 25%
• Titanium Oxide 25%
• Photocatalysts 25%

Chemical Engineering

• Nanoparticle 100%
• Nanotube 100%
• Photodegradation 100%
• Phenol 66%
• Morphology 33%
• Photocatalytic Degradation 16%
• Enhanced Photocatalytic Activity 16%
• Titanium Oxide 16%
• Phenol Degradation 16%