Material Science
Monolayers
100%
Transition Metal Dichalcogenide
66%
Two-Dimensional Material
57%
Heterojunction
41%
Film
33%
Graphene
24%
Electronic Property
24%
Oxide Compound
21%
Superlattice
20%
Epitaxy
14%
Carrier Concentration
11%
Crystalline Material
10%
Tungsten
9%
Optical Property
9%
Optical Pumping
9%
Lithography
9%
Semiconducting Film
9%
Doping (Additives)
9%
Coupling Constant
9%
Multilayer Film
9%
Chemical Vapor Deposition
9%
Density
8%
Ultrafast Spectroscopy
6%
Contact Resistance
6%
Defect Density
6%
Electrical Conductivity
5%
Thin Films
5%
Photoluminescence
5%
Physical Property
5%
Metal-Organic Chemical Vapor Deposition
5%
Physics
Transition Metal Dichalcogenide
30%
Exciton
30%
Heterojunctions
21%
Two-Dimensional Materials
18%
Binding Energy
14%
Scanning Tunneling Microscopy
12%
Magnetic Field
9%
Phonon
9%
Optical Pumping
9%
Single Crystal
9%
Grain Boundaries
9%
Optical Measurement
9%
Photoluminescence
9%
Metalorganic Chemical Vapor Deposition
9%
Electrostatics
9%
Coupling Constant
9%
Energy Gaps (Solid State)
9%
Silicon Oxide
9%
Polycrystalline
9%
Superlattice
9%
Lattice Mismatch
7%
Electron Beam
7%
Photoelectric Emission
7%
Diffraction Pattern
7%
Keyphrases
Band Gap
15%
Transition Metal Dichalcogenides
12%
Monolayer FeSe
9%
Optical Pumping
9%
Biexciton
9%
Monolayer MoS2
9%
Molybdenite
9%
Edge Contact
9%
Remote Epitaxy
9%
Oxide Membrane
9%
Complex Oxides
9%
Electron Ptychography
9%
Layer-by-layer Assembly
9%
Metal-doped
9%
Metal-induced Gap States
9%
Highly Doped
9%
MoS2 Monolayer
9%
Friedel's Law
9%
Few-layer WS2
9%
Spin-valley Polarization
9%
High Electrical Performance
6%
Transition Metal Dichalcogenide Monolayer
6%
Electrical Contact
6%
Optically Induced
6%
Moiré Band
6%
Substitutional Dopant
6%
Electronic Properties
6%