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Energy band gap of titanium nitride films deposited on a silicon... | Download Scientific Diagram
Energy band gap of titanium nitride films deposited on a silicon... | Download Scientific Diagram

Epitaxial Nitride Thin Film and Heterostructures: From Hard Coating to Solid State Energy Conversion | IntechOpen
Epitaxial Nitride Thin Film and Heterostructures: From Hard Coating to Solid State Energy Conversion | IntechOpen

Discovery of Ternary Silicon Titanium Nitride with Spinel-Type Structure | Scientific Reports
Discovery of Ternary Silicon Titanium Nitride with Spinel-Type Structure | Scientific Reports

Sub-Band Gap Photodetection from the Titanium Nitride/Germanium Heterostructure. | Semantic Scholar
Sub-Band Gap Photodetection from the Titanium Nitride/Germanium Heterostructure. | Semantic Scholar

Computational Dissection of Two-Dimensional Rectangular Titanium Mononitride TiN: Auxetics and Promises for Photocatalysis
Computational Dissection of Two-Dimensional Rectangular Titanium Mononitride TiN: Auxetics and Promises for Photocatalysis

Hot Electron Excitation from Titanium Nitride Using Visible Light
Hot Electron Excitation from Titanium Nitride Using Visible Light

Predicting the structure and stability of titanium oxide electrides | npj Computational Materials
Predicting the structure and stability of titanium oxide electrides | npj Computational Materials

Optimizing hot electron harvesting at planar metal-semiconductor interfaces with titanium oxynitride thin films
Optimizing hot electron harvesting at planar metal-semiconductor interfaces with titanium oxynitride thin films

Tuning the optical bandgap of TiO2-TiN composite films as photocatalyst in the visible light: AIP Advances: Vol 3, No 6
Tuning the optical bandgap of TiO2-TiN composite films as photocatalyst in the visible light: AIP Advances: Vol 3, No 6

Ultra-thin titanium nitride films for refractory spectral selectivity [Invited]
Ultra-thin titanium nitride films for refractory spectral selectivity [Invited]

Sub-Band Gap Photodetection from the Titanium Nitride/Germanium Heterostructure. | Semantic Scholar
Sub-Band Gap Photodetection from the Titanium Nitride/Germanium Heterostructure. | Semantic Scholar

Engineering the band gap of Hf2CO2 MXene semiconductor by C/O doping | SpringerLink
Engineering the band gap of Hf2CO2 MXene semiconductor by C/O doping | SpringerLink

Design of Metastable Tin Titanium Nitride Semiconductor Alloys
Design of Metastable Tin Titanium Nitride Semiconductor Alloys

Sub-Band Gap Photodetection from the Titanium Nitride/Germanium Heterostructure. | Semantic Scholar
Sub-Band Gap Photodetection from the Titanium Nitride/Germanium Heterostructure. | Semantic Scholar

Catalysts | Free Full-Text | Graphitic Carbon Nitride Materials for Photocatalytic Hydrogen Production via Water Splitting: A Short Review
Catalysts | Free Full-Text | Graphitic Carbon Nitride Materials for Photocatalytic Hydrogen Production via Water Splitting: A Short Review

First-principles study of phase stability of Ti2N under pressure
First-principles study of phase stability of Ti2N under pressure

Materials | Free Full-Text | Optical Properties and Plasmonic Performance of Titanium Nitride
Materials | Free Full-Text | Optical Properties and Plasmonic Performance of Titanium Nitride

Calculated electronic band structure of (a) TiN, (b) ZrN along high... | Download Scientific Diagram
Calculated electronic band structure of (a) TiN, (b) ZrN along high... | Download Scientific Diagram

Broadband Hot‐Electron Collection for Solar Water Splitting with Plasmonic Titanium Nitride - Naldoni - 2017 - Advanced Optical Materials - Wiley Online Library
Broadband Hot‐Electron Collection for Solar Water Splitting with Plasmonic Titanium Nitride - Naldoni - 2017 - Advanced Optical Materials - Wiley Online Library

Band engineering of ternary metal nitride system Ti1-x ZrxN for plasmonic applications
Band engineering of ternary metal nitride system Ti1-x ZrxN for plasmonic applications

Tuning the optical bandgap of TiO2-TiN composite films as photocatalyst in the visible light: AIP Advances: Vol 3, No 6
Tuning the optical bandgap of TiO2-TiN composite films as photocatalyst in the visible light: AIP Advances: Vol 3, No 6

Sub-Band Gap Photodetection from the Titanium Nitride/Germanium Heterostructure | ACS Applied Materials & Interfaces
Sub-Band Gap Photodetection from the Titanium Nitride/Germanium Heterostructure | ACS Applied Materials & Interfaces

Epitaxial Nitride Thin Film and Heterostructures: From Hard Coating to Solid State Energy Conversion | IntechOpen
Epitaxial Nitride Thin Film and Heterostructures: From Hard Coating to Solid State Energy Conversion | IntechOpen

Calculated band structure and density of states of TiN. | Download Scientific Diagram
Calculated band structure and density of states of TiN. | Download Scientific Diagram

SciELO - Brasil - Incorporation of N in the TiO<sub>2</sub> Lattice <i>Versus</i> Oxidation of TiN: Influence of the Deposition Method on the Energy Gap of N-Doped TiO<sub>2</sub> Deposited by Reactive Magnetron Sputtering
SciELO - Brasil - Incorporation of N in the TiO<sub>2</sub> Lattice <i>Versus</i> Oxidation of TiN: Influence of the Deposition Method on the Energy Gap of N-Doped TiO<sub>2</sub> Deposited by Reactive Magnetron Sputtering

Band gap E g and nitrogen content of selected samples. | Download Table
Band gap E g and nitrogen content of selected samples. | Download Table

Semiconducting Cubic Titanium Nitride in the Th3P4 Structure. Article No. 011602(R)
Semiconducting Cubic Titanium Nitride in the Th3P4 Structure. Article No. 011602(R)