Ultrathin TiN Epitaxial Films as Transparent Conductive Electrodes

Keyphrases

• Ultrathin 100%
• Epitaxial Film 100%
• Transparent Electrode 100%
• Titanium Nitride 100%
• Titanium Nitride Film 57%
• Surface Morphology 28%
• Molecular Beam Epitaxy 14%
• Thermal Evaporation 14%
• Reactive Sputtering 14%
• Tight 14%
• Electrical Conductivity 14%
• Electrical Properties 14%
• Terahertz Spectroscopy 14%
• Dielectric Properties 14%
• Hall Effect 14%
• Deposition Methods 14%
• Smooth Surface 14%
• Ultra-high Vacuum 14%
• Optical Transmittance 14%
• Noble Metals 14%
• Spectroscopic Ellipsometry 14%
• Mechanical Stability 14%
• Root-mean-square Roughness 14%
• Surface Scattering 14%
• Visible Regime 14%
• Oxygen Content 14%
• Plasma-assisted Molecular Beam Epitaxy 14%
• Nitrogen Plasma 14%
• Vacuum Environment 14%
• Chemical Stability 14%
• High Melting Temperature 14%
• Metallic Layer 14%
• Ti-N 14%
• High Optical Transparency 14%
• Excellent Electrical Conductivity 14%
• Thickness Reduction 14%
• Metal Oxide Electrode 14%
• Transition Metal Compounds 14%

Material Science

• Nitride Compound 100%
• Titanium 100%
• Epitaxial Film 100%
• Film 44%
• Surface Morphology 22%
• Molecular Beam Epitaxy 22%
• Electrical Conductivity 22%
• Transition Metal 11%
• Terahertz Spectroscopy 11%
• Dielectric Property 11%
• Percolation 11%
• Metal Oxide 11%
• Surface (Surface Science) 11%