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Atomic, Molecular & Optical
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Atomic, Molecular & Optical
More specific terms
NT1
↓
Adiabatic approximation
NT1
↓
Atom interferometry
►
▼
NT2
↓
Mach-Zehnder atom interferometry
NT1
↓
Atomic & molecular collisions
►
▼
NT2
↓
Atom or molecule scattering from surfaces
►
▼
NT3
↓
Helium atom scattering
NT2
↓
Chemical reactions
NT2
↓
Electron & positron scattering
NT2
↓
Electronic excitation & ionization
NT2
↓
Interatomic & molecular potentials
NT2
↓
Scattering of atoms, molecules, clusters & ions
►
▼
NT3
↓
Charge-transfer collisions
NT2
↓
Scattering theory
NT2
↓
Ultracold collisions
NT1
↓
Atomic & molecular processes in external fields
►
▼
NT2
↓
Atomic, optical & lattice clocks
NT2
↓
Autoionization & Auger processes
NT2
↓
Coherent control
NT2
↓
Cooling & trapping
►
▼
NT3
↓
Atom & ion cooling
NT3
↓
Atom & ion trapping & guiding
NT3
↓
Molecule trapping & guiding
NT3
↓
Optical lattices & traps
►
▼
NT4
↓
BEC-BCS crossover
NT3
↓
Penning traps
NT2
↓
Electro-optical spectra
NT2
↓
Laser-cluster interaction
NT2
↓
Magneto-optical spectra
NT2
↓
Multiphoton or tunneling ionization & excitation
►
▼
NT3
↓
High-order harmonic generation
NT2
↓
Nuclear & electron resonance
NT2
↓
Optical pumping
NT2
↓
Optical transient phenomena
NT2
↓
Photoassociation
NT2
↓
Photodetachment
NT2
↓
Photodissociation
NT2
↓
Photoemission
NT2
↓
Single- and few-photon ionization & excitation
NT2
↓
Spontaneous emission
NT2
↓
Stark effect
NT2
↓
Strong electromagnetic field effects
►
▼
NT3
↓
Strong field excitation
NT3
↓
Strong-field-induced spectra
NT3
↓
Ultrashort pulses
NT2
↓
Ultrafast phenomena
NT2
↓
Zeeman effect
NT1
↓
Atomic & molecular structure
►
▼
NT2
↓
Atomic & molecular clusters
►
▼
NT3
↓
Collective effects in clusters
NT3
↓
Diffusion & dynamics of clusters
NT3
↓
Electronic & magnetic properties of clusters
NT3
↓
Optical properties of clusters
NT3
↓
Phase transitions in clusters
NT3
↓
Reactivity of clusters
NT3
↓
Spectroscopy of clusters
NT3
↓
Stability of clusters
NT2
↓
Atomic orbital
NT2
↓
Atomic spectra
►
▼
NT3
↓
Lifetimes & widths
NT3
↓
Oscillator strength
NT3
↓
Relativistic effects in atomic spectra
NT2
↓
Casimir effect & related phenomena
NT2
↓
Chemical binding
NT2
↓
Electron correlation calculations for atoms & ions
NT2
↓
Electronic structure of atoms & molecules
NT2
↓
Electronic transitions
NT2
↓
Fine & hyperfine structure
NT2
↓
Long-range interactions
NT2
↓
Molecular spectra
NT2
↓
Potential energy surfaces
NT2
↓
Relativistic & quantum electrodynamic effects in atoms, molecules,& ions
NT2
↓
Van der Waals interaction
NT1
↓
Atomic Properties
►
▼
NT2
↓
Electric moment
NT2
↓
Electron affinity
NT2
↓
Magnetic moment
NT2
↓
Polarizability
NT2
↓
Polarization
NT1
↓
Atomic systems
►
▼
NT2
↓
Atomic & molecular beams
NT2
↓
Atomic ensemble
NT2
↓
Atomic gases
►
▼
NT3
↓
Bose gases
NT3
↓
Fermi gases
NT2
↓
Atoms
NT2
↓
Clusters
NT2
↓
Exotic atoms & molecules
NT2
↓
Ions
NT2
↓
Molecules
NT2
↓
Muonic atoms & molecules
NT2
↓
Muonium
NT2
↓
Positronium
NT2
↓
Rydberg atoms & molecules
NT2
↓
Trapped ions
NT1
↓
Beam splitters
NT1
↓
Cold atoms & matter waves
►
▼
NT2
↓
Anderson localization
NT2
↓
Atom interferometry
►
▼
NT3
↓
Mach-Zehnder atom interferometry
NT2
↓
Atom lasers
NT2
↓
Atom optics
NT2
↓
Bose gases
NT2
↓
Bose-Einstein condensates
►
▼
NT3
↓
Spinor Bose-Einstein condensates
NT2
↓
Cold and ultracold molecules
NT2
↓
Cold gases in optical lattices
►
▼
NT3
↓
Many-body effects
►
▼
NT4
↓
Topological phases in many body systems
NT3
↓
Optical ladders
NT2
↓
Decoherence in quantum gases
NT2
↓
Dipolar gases
NT2
↓
Entanglement in quantum gases
NT2
↓
Fermi gases
NT2
↓
Fermionic condensates
NT2
↓
Mixtures of atomic and/or molecular quantum gases
►
▼
NT3
↓
Bose-Fermi mixtures
NT2
↓
Neutron optics
NT2
↓
Spin-orbit coupling
►
▼
NT3
↓
Dresselhaus coupling
NT3
↓
Dzyaloshinskii-Moriya interaction
NT3
↓
Rashba coupling
NT2
↓
Synthetic gauge fields
NT1
↓
Complex media
►
▼
NT2
↓
Random & disordered media
NT1
↓
Cooling & trapping
►
▼
NT2
↓
Atom & ion cooling
NT2
↓
Atom & ion trapping & guiding
NT2
↓
Molecule trapping & guiding
NT2
↓
Optical lattices & traps
►
▼
NT3
↓
BEC-BCS crossover
NT2
↓
Penning traps
NT1
↓
Dipole approximation
NT1
↓
Feshbach resonance
NT1
↓
First-principles calculations
►
▼
NT2
↓
Basis sets
►
▼
NT3
↓
Plane wave
NT2
↓
Density functional theory
►
▼
NT3
↓
Density functional approximations
►
▼
NT4
↓
DFT+DMFT
NT4
↓
DFT+U
NT4
↓
GGA
NT4
↓
Hybrid functionals
NT4
↓
LDA
NT4
↓
LDA+DMFT
NT4
↓
LDA+U
NT4
↓
Meta-GGA
NT4
↓
Pseudopotentials
NT4
↓
Time-dependent DFT
NT3
↓
Density functional calculations
NT3
↓
Density functional theory development
NT2
↓
GW method
NT2
↓
High-throughput calculations
NT2
↓
Quantum chemistry methods
►
▼
NT3
↓
Configuration interaction
NT3
↓
Coupled cluster
NT3
↓
Hartree-Fock methods
NT3
↓
Molecular orbital theory
NT1
↓
Hartree-Fock methods
NT1
↓
Laser systems
►
▼
NT2
↓
Chemical lasers
NT2
↓
Dye lasers
NT2
↓
Fiber lasers
NT2
↓
Gas lasers
NT2
↓
Liquid crystal lasers
NT2
↓
Microcavity & microdisk lasers
NT2
↓
Photonic crystal lasers
NT2
↓
Raman lasers
NT2
↓
Random lasers
NT2
↓
Solid state lasers
►
▼
NT3
↓
Diode lasers
NT3
↓
Semiconductor lasers
►
▼
NT4
↓
Quantum cascade lasers
NT3
↓
VCSELs
NT2
↓
Tunable lasers
NT2
↓
X-ray lasers
NT1
↓
Micromechanical & nanomechanical oscillators
NT1
↓
Molecular dynamics
NT1
↓
Nitrogen vacancy centers in diamond
NT1
↓
Nonperturbative methods
NT1
↓
Optical materials & elements
►
▼
NT2
↓
Bragg structures
NT2
↓
Optical fibers
NT2
↓
Optical microcavities
NT2
↓
Optical sources & detectors
NT2
↓
Organic microcavities
NT2
↓
Quantum cavities
NT2
↓
Semiconductor microcavities
NT2
↓
Waveguides
►
▼
NT3
↓
Waveguide arrays
NT1
↓
Optical sources
NT1
↓
Optical techniques
►
▼
NT2
↓
Cavity resonators
►
▼
NT3
↓
Whispering gallery mode resonators
NT2
↓
Coherent control
NT2
↓
Confocal imaging
NT2
↓
Electroluminescence
NT2
↓
Ellipsometry
NT2
↓
Fluorescence spectroscopy
NT2
↓
Four-wave mixing
NT2
↓
High-harmonic generation
►
▼
NT3
↓
Optical second-harmonic generation
NT2
↓
Homodyne & heterodyne detection
NT2
↓
Imaging & optical processing
►
▼
NT3
↓
Ghost imaging
NT3
↓
Holography
NT3
↓
Tomography
NT2
↓
Kerr effect
►
▼
NT3
↓
Magneto-optical Kerr effect
►
▼
NT4
↓
Surface magneto-optical Kerr effect
NT2
↓
Laser techniques
►
▼
NT3
↓
Attosecond laser irradiation
NT3
↓
Attosecond laser spectroscopy
NT3
↓
Femtosecond laser irradiation
NT3
↓
Femtosecond laser spectroscopy
NT3
↓
Laser ablation
NT3
↓
Laser-beam impact phenomena
NT3
↓
Optical pumping
NT3
↓
Optical tweezers
NT3
↓
Pump-probe spectroscopy
►
▼
NT4
↓
Transient absorption spectroscopy
NT4
↓
Ultrafast pump-probe spectroscopy
NT3
↓
Two-photon polymerization
NT2
↓
Light scattering
►
▼
NT3
↓
Diffusive wave spectroscopy
NT3
↓
Inelastic light scattering
NT3
↓
Photon correlation spectroscopy
NT3
↓
Static light scattering
NT3
↓
Time-resolved light scattering spectroscopy
NT2
↓
Luminescence
NT2
↓
Optical desorption spectroscopy
NT2
↓
Optical interferometry
NT2
↓
Optical metallography
NT2
↓
Optical microscopy
►
▼
NT3
↓
Annular dark-field imaging
NT3
↓
Dark-field microscopy
NT3
↓
Phase contrast optical microscopy
NT3
↓
Polarized optical microscopy
NT2
↓
Optical nanoscopy
NT2
↓
Photoexcitation
NT2
↓
Photoionization
NT2
↓
Photoluminescence
►
▼
NT3
↓
Fluorescence
►
▼
NT4
↓
Fluorescence recovery after photobleaching
NT4
↓
Light sheet fluorescence microscopy
NT3
↓
Phosphorescence
NT3
↓
Time-resolved photoluminescence
NT2
↓
Photon counting
NT2
↓
Reflectivity
NT1
↓
Optics & lasers
►
▼
NT2
↓
Angular momentum of light
►
▼
NT3
↓
Optical vortices
NT2
↓
Classical optics
►
▼
NT3
↓
Geometrical & wave optics
NT3
↓
Imaging & optical processing
►
▼
NT4
↓
Ghost imaging
NT4
↓
Holography
NT4
↓
Tomography
NT3
↓
Interference & diffraction of light
NT3
↓
Light propagation, transmission & absorption
NT3
↓
Optical interferometry
NT3
↓
Polarization of light
NT3
↓
Transformation optics
NT2
↓
Dichroism
NT2
↓
Effects of atomic coherence on light propagation
►
▼
NT3
↓
Coherent population trapping
NT3
↓
Electromagnetically induced transparency
NT3
↓
Lasing without inversion
NT3
↓
Stimulated Raman adiabatic passage
NT2
↓
Electron beams & optics
NT2
↓
Lasers
►
▼
NT3
↓
Frequency combs & self-phase locking
NT3
↓
Laser applications
NT3
↓
Laser dynamics
NT3
↓
Laser spectroscopy
NT3
↓
Laser theory
NT3
↓
Laser-system design
NT3
↓
Spatial profiles of optical beams
NT2
↓
Light-matter interaction
►
▼
NT3
↓
Atoms, ions, & molecules in cavities
NT3
↓
Mechanical effects of light on material media
NT3
↓
Mie scattering
NT3
↓
Quantum description of light-matter interaction
NT2
↓
Masers
NT2
↓
Metamaterials
►
▼
NT3
↓
Acoustic metamaterials
NT3
↓
Hyperbolic metamaterials
NT3
↓
Magnonic crystals
NT3
↓
Negative refraction
NT3
↓
Optical cloaking
NT3
↓
Split-ring resonators
NT2
↓
Near-field optics
NT2
↓
Nonlinear optics
►
▼
NT3
↓
Brillouin scattering & spectroscopy
►
▼
NT4
↓
Brillouin light spectroscopy
NT3
↓
High-order harmonic generation
NT3
↓
Multiwave mixing
NT3
↓
Nonlinear optical susceptibility
NT3
↓
Nonlinear waveguides
NT3
↓
Optical bistability
NT3
↓
Optical chaos
NT3
↓
Optical parametric oscillators & amplifiers
NT3
↓
Optical solitons
NT3
↓
Phase conjugation
NT3
↓
Photorefractive & Kerr effects
NT3
↓
Rayleigh scattering
NT3
↓
Second order nonlinear optical processes
NT3
↓
Stimulated Raman scattering
NT3
↓
Third order nonlinear optical processes
NT3
↓
Upconversion
NT2
↓
Optical coherence
NT2
↓
Optical materials & elements
►
▼
NT3
↓
Bragg structures
NT3
↓
Optical fibers
NT3
↓
Optical microcavities
NT3
↓
Optical sources & detectors
NT3
↓
Organic microcavities
NT3
↓
Quantum cavities
NT3
↓
Semiconductor microcavities
NT3
↓
Waveguides
►
▼
NT4
↓
Waveguide arrays
NT2
↓
Optical photonics
NT2
↓
Optomechanics
NT2
↓
Orbital angular momentum
NT2
↓
Photonic crystals
NT2
↓
Photonics
►
▼
NT3
↓
Integrated optics
NT3
↓
Nanophotonics
NT3
↓
Topological effects in photonic systems
NT2
↓
Plasmonics
NT2
↓
Quantum optics
►
▼
NT3
↓
Cavity quantum electrodynamics
NT3
↓
Collective effects in quantum optics
►
▼
NT4
↓
Superradiance & subradiance
NT3
↓
Hybrid quantum systems
NT3
↓
Optical tests of quantum theory
NT3
↓
Photon pairs & parametric down-conversion
NT3
↓
Photon statistics
NT3
↓
Quantum fluctuations & noise
NT3
↓
Quantum measurements
NT3
↓
Quantum optics with artificial atoms
NT3
↓
Quantum state engineering
NT3
↓
Quantum states of light
NT3
↓
Semiconductor quantum optics
NT3
↓
Single photon sources
NT3
↓
Squeezing of quantum noise
NT3
↓
Superconducting quantum optics
NT2
↓
Superfluorescence
NT2
↓
Ultrafast optics
NT2
↓
X-ray beams & optics
NT1
↓
Perturbative methods
NT1
↓
Phase space methods
NT1
↓
Polarizers
NT1
↓
Quantum dots
►
▼
NT2
↓
Double quantum dots
NT1
↓
Quantum fluids & solids
►
▼
NT2
↓
Bose-Einstein condensates
►
▼
NT3
↓
Spinor Bose-Einstein condensates
NT2
↓
Fermionic condensates
NT2
↓
Molecular condensates
NT2
↓
Polariton condensate
NT2
↓
Superfluids
►
▼
NT3
↓
Helium-3 superfluids
NT3
↓
Helium-4 superfluids
NT3
↓
Mixtures of 3He & 4He
NT3
↓
Mott superfluids
NT2
↓
Supersolids
NT2
↓
Ultracold gases
NT1
↓
Quantum Monte Carlo
►
▼
NT2
↓
Diffusion quantum Monte Carlo
NT1
↓
Quantum orbits theory
NT1
↓
Random phase approximation
NT1
↓
Rare-earth doped crystals
NT1
↓
Resonance techniques
►
▼
NT2
↓
Cyclotron resonance
NT2
↓
Dynamic nuclear polarization
NT2
↓
Electron nuclear double resonance
NT2
↓
Electron paramagnetic resonance
NT2
↓
Electron spin resonance
NT2
↓
Ferromagnetic resonance
NT2
↓
Mössbauer spectroscopy
►
▼
NT3
↓
Mössbauer emission spectroscopy
NT2
↓
Muon spin resonance
NT2
↓
Nuclear magnetic resonance
►
▼
NT3
↓
Functional magnetic resonance imaging
NT3
↓
Magnetic resonance imaging
NT2
↓
Nuclear quadrupole resonance
NT2
↓
Nuclear spin resonance
NT2
↓
Optically detected magnetic resonance
NT2
↓
Tunnel diode resonance
NT1
↓
Rotating wave approximation
NT1
↓
Schroedinger equation
NT1
↓
Semiclassical methods
NT1
↓
Spectroscopy
►
▼
NT2
↓
Bragg spectroscopy
NT2
↓
Optical spectroscopy
►
▼
NT3
↓
Dark-field optical spectroscopy
NT3
↓
Dielectric spectroscopy
NT3
↓
Femtosecond laser spectroscopy
NT3
↓
Near-field optical spectroscopy
NT3
↓
Optical absorption spectroscopy
NT3
↓
Pump-probe spectroscopy
►
▼
NT4
↓
Transient absorption spectroscopy
NT4
↓
Ultrafast pump-probe spectroscopy
NT3
↓
Time-resolved light scattering spectroscopy
NT3
↓
Time-resolved reflection spectroscopy
NT1
↓
Stochastic differential equations
NT1
↓
Strong-field approximation
NT1
↓
Super-resolution techniques
NT1
↓
Two-level models
►
▼
NT2
↓
Dicke model
NT2
↓
Jaynes-Cummings model
NT2
↓
Rabi model
NT2
↓
Tavis-Cummings model
NT1
↓
Weak measurements
NT1
↓
X-ray techniques
►
▼
NT2
↓
Energy spectroscopy for chemical analysis
NT2
↓
Energy-dispersive x-ray spectroscopy
NT2
↓
Hard x-ray photoelectron spectroscopy
NT2
↓
X-ray absorption spectroscopy
►
▼
NT3
↓
X-ray absorption fine structure spectroscopy
NT3
↓
X-ray absorption near-edge spectroscopy
NT2
↓
X-ray diffraction
►
▼
NT3
↓
Grazing incidence X-ray diffraction
NT3
↓
X-ray diffraction topography
NT3
↓
X-ray powder diffraction
NT2
↓
X-ray emission spectroscopy
NT2
↓
X-ray fluorescence holography
NT2
↓
X-ray holography
NT2
↓
X-ray imaging
NT2
↓
X-ray magnetic circular dichroism
NT2
↓
X-ray magnetic linear dichroism
NT2
↓
X-ray pair-distribution function analysis
NT2
↓
X-ray photoelectron diffraction
NT2
↓
X-ray photoelectron spectroscopy
NT2
↓
X-ray photoemission electron microscopy
NT2
↓
X-ray photon correlation spectroscopy
NT2
↓
X-ray reflectivity
NT2
↓
X-ray scattering
►
▼
NT3
↓
Coherent X-ray scattering
NT3
↓
Resonant elastic x-ray scattering
NT3
↓
Resonant inelastic x-ray scattering
NT3
↓
Small-angle x-ray scattering
NT3
↓
X-ray diffuse scattering
NT3
↓
X-ray resonant magnetic scattering
NT2
↓
X-ray standing waves
NT2
↓
X-ray tomography
Date of creation
14-Sep-2018
Modified
15-Sep-2018
Accepted term
14-Sep-2018
Descendant terms
225
ARK
ark:/99152/t3k67z608wz41x
More specific terms
44
Alternative terms
0
Related terms
0
Notes
0
Metadata
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Central terms
Optics & lasers
Atomic & molecular processes in external fields
Cold atoms & matter waves
Atomic & molecular structure
Atomic systems
Quantum fluids & solids
Atomic & molecular collisions
Atomic Properties
Two-level models
Complex media