Thomas Garm Pedersen

M. Sc. Engineering (optics), PhD (see homepage for full CV)

  • Skjernvej 4, A, 5-118

    9220 Aalborg Ø

    Denmark

19962020
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Chemical Compounds

Absorption spectra
Adsorption
Analytical models
Anisotropy
Band structure
Binding energy
Birefringence
Carbon Nanotubes
Charge carriers
Coulomb interactions
Crystalline materials
Delta functions
Doping (additives)
Electric fields
Electrons
Energy gap
Faraday effect
Fermions
Gages
Geometry
Graphite
Harmonic generation
Heterojunctions
Hydrogen
Impurities
Invariance
LDS 751
Light absorption
Liquids
Magnetic fields
Magnetooptical effects
Mean field theory
Metalloporphyrins
Monolayers
Nonlinear optics
Optical conductivity
Optical data storage
Optical properties
Optoelectronic devices
Orbits
Phosphorus
Polymers
Porphyrins
Pumps
Semiconductor quantum dots
Semiconductor quantum wells
Single-walled carbon nanotubes (SWCN)
Stark effect
Transition metals
Tuning

Physics & Astronomy

Aerospace Sciences

magnetic fields

Chemistry and Materials

liquids
phosphorus
polymers
porphyrins

Engineering

binding energy
carbon nanotubes
free electrons
gauge invariance
graphene
interlayers
nanowires
pumps
quantum dots
quantum mechanics
solar cells
tuning

General

anisotropy
Bessel functions
conductivity
dissociation
electric fields
energy
expansion
exponential functions
instantons
interactions
intersections
magneto-optics
optical transition
quantum electronics
radii
retraining
shift
Stark effect
sum rules
transition metals

Mathematical and Computer Sciences

approximation
perturbation theory
tensors

Physics

atomic energy levels
charged particles
electro-optics
electrons
excitons
Faraday effect
harmonic generations
light scattering
optical absorption
perturbation

Engineering & Materials Science

Absorption spectra
Adsorption
Analytical models
Anisotropy
Band structure
Binding energy
Carbon nanotubes
Charge carriers
Crystalline materials
Current density
Delta functions
Doping (additives)
Electric fields
Electrons
Energy gap
Equations of motion
Excitons
Faraday effect
Fermions
Gages
Geometry
Graphene
Hamiltonians
Harmonic generation
Heterojunctions
Hydrogen
Impurities
Invariance
Light absorption
Magnetic fields
Magnetooptical effects
Mean field theory
Monolayers
Nanoribbons
Nonlinear optics
Optical conductivity
Optoelectronic devices
Orbits
Phosphorus
Polymers
Porphyrins
Pumps
Screening
Semiconductor materials
Semiconductor quantum dots
Semiconductor quantum wells
Single-walled carbon nanotubes (SWCN)
Stark effect
Transition metals
Tuning