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Resonance Raman scattering from a multilevel, thermally relaxing system
S. Mukamel
*
,
A. Nitzan
*
Corresponding author for this work
School of Chemistry
Tel Aviv University
Research output
:
Contribution to journal
›
Article
›
peer-review
37
Scopus citations
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Keyphrases
Coherent Raman Scattering
33%
Damping Term
33%
Dense Phase
33%
Energy Broadening
33%
Excited States
33%
Gas Phase
33%
Heat Bath
33%
Impurities
33%
Incident Radiation
33%
Interaction with Environment
33%
Interference Phenomena
33%
Light Scattering
100%
Liouville Space
33%
Luminescence
33%
Molecular Energy Levels
66%
Molecular Space
33%
Multilevel Systems
33%
Non-diagonal
33%
Non-radial
33%
Physical Interpretation
33%
Quasi-elastic
33%
Quenching Process
33%
Radiation Field
33%
Radiation Intensity
33%
Radiative Damping
33%
Relative Yield
33%
Resonance Raman Scattering
100%
Scattering Processes
66%
Temperature Effect
33%
Temperature Process
33%
Thermal Bath
66%
Thermal Relaxation
66%
Zero Temperature
33%
Engineering
Broadening
50%
Cross Section
50%
Damping Term
50%
Dense Phase
50%
Excited State
50%
Field Mode
50%
Gas-Phase
50%
Incident Radiation
50%
Liouville
50%
Radiation Field
50%
Radiation Intensity
50%
Raman Spectra
100%
Temperature Dependence
50%
Thermal Relaxation
100%
Physics
Incident Radiation
33%
Light Scattering
100%
Molecular Energy Levels
66%
Radiant Flux Density
33%
Radiation Distribution
33%
Raman Spectra
100%
Temperature Dependence
33%
Zero-Temperature
33%
Chemistry
Excited State
33%
Light Scattering
100%
Raman Spectra
100%
Relaxation
100%
Zero-Temperature
33%