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Physical models for quantum wires, nanotubes, and nanoribbons
Jean Pierre Leburton
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Dive into the research topics of 'Physical models for quantum wires, nanotubes, and nanoribbons'. Together they form a unique fingerprint.
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Keyphrases
Nanoribbon
100%
Nanotubes
100%
Physical Model
100%
Quantum Wire
100%
Physical Properties
50%
Numerical Simulation
50%
Monte Carlo Method
50%
Charge Carriers
50%
Analytical Techniques
50%
Carbon Nanotubes
50%
Density Functional Theory
50%
Transport Effects
50%
Quantum Confined
50%
Lattice Vibration
50%
Boltzmann Equation
50%
Graphene Nanoribbon
50%
Molecular Structure
50%
Quantum Spin
50%
Quantum Confinement
50%
Scattering Rate
50%
Charged Particles
50%
Charge Transport
50%
Nonequilibrium Green's Function
50%
Nanoelectronics
50%
Carrier Scattering
50%
Semiconductor Structures
50%
Quantum Transport
50%
Single Degree of Freedom
50%
Spin Effects
50%
Artificial Structures
50%
Standing Modes
50%
Engineering
Nanotube
100%
Physical Model
100%
Quantum Wire
100%
Graphene
50%
Nanoscale
50%
Boltzmann Equation
50%
Green Function
50%
Cross Section
50%
Charge Carrier
50%
Computer Simulation
50%
Carbon Nanotube
50%
Nonequilibrium
50%
Degree of Freedom
50%
Quantum Confinement
50%
Nanoelectronics
50%
Charge Transport
50%
Semiconductor Structure
50%
Single Degree
50%
Material Science
Nanoribbon
100%
Nanotube
100%
Analytical Method
50%
Density
50%
Charge Carrier
50%
Carbon Nanotube
50%
Graphene
50%
Lattice Vibration
50%
Physical Property
50%
Molecular Structure
50%
Semiconductor Structure
50%