Energy Transfer and Cooperative Optical Transitions in Rare-Earth Doped Inorganic Materials. : III. Dominant Transfer Mechanism
スポンサーリンク
概要
- 論文の詳細を見る
Estimations are made of the critical concentration of energy-acceptor ions for which the average efficiency of the excitation transfer from energy-donor ions is 1/2. This gives a measure of the activator concentration at which Inokuti and Hirayama's theory is no longer applicable. Study is also made of the dominant multipole interaction responsible for the energy transfer between rare earth ions in inorganic solids. Finally, importance of the J-selection rule in the determination of the dominant interaction term in the resonance transfer and cooperative processes is emphasized.
- 社団法人日本物理学会の論文
- 1973-05-05
著者
関連論文
- Spontaneous and Stimulated Emissions in Highly Excited GaAs
- Phonon-Assisted Energy Transfer between Trivalent Rare Earth Ions
- Phonon-Assisted Energy Transfer : Comparison between Theory and Experiment
- Mechanism and Controlling Factors of Infrared-to-Visible Conversion Process in Er^ and Yb^-Doped Phosphors
- Optical Studies of Resonantly Excited Excitonic Molecules in CuCl
- Picosecond Time Analysis of Excitonic Molecule Luminescence Spectra in CuCl
- Tunable Picosecond Pulse Generation by Optical Parametric Oscillator
- Generation of Widely Tunable Pico-Second Pulses by Optical Parametric Effect
- Absorption Spectra of Optically Pumped ZnS:Mn
- Resonance Raman Scattering in Cuprous Halides
- Temperature Dependence of Raman Scattering and Exciton Luminescence Spectra in ZnTe
- Resonance Raman Scattering in CdS and ZnO by Tunable Dye Laser
- Luminescence Spectra Due to Exciton-Exditon Collisions in Semiconductors. : I. Spontaneous Emission Spectra
- Luminescence Spectra Due to Exciton-Exciton Collisions in Semiconductors. : II. Stimulated Emission Spectra
- Energy Transfer and Cooperative Optical Transitions in Rare-Earth Doped Inorganic Materials. : I. Transition Probability Calculation
- Energy Transfer and Cooperative Optical Transitions in Rare-Earth Doped Inorganic Materials. : III. Dominant Transfer Mechanism
- Luminescence Due to High-Density Electron-Hole Plasma in GaAs
- Energy Transfer and Cooperative Optical Transitions In Rare-Earth Doped Inorganic Materials. : II. Comparison with Experiments