Stochastic Models of Intermediate State Interaction in Second Order Optical Processes : Stationary Response. : I
スポンサーリンク
概要
- 論文の詳細を見る
A general theory of the intermediate state interaction in the second order opticalprocess is developed by extending the stochastic theory of line shape. We introduce thestochastic models of the intermediate state interaction and discuss the general featuresof the secondary emission spectrum, focusing particular attention on how the cor-relation between the incident and the scattered photons are affected by the intermediatestate interaction. It is clarified how the spectral features or the relative weights amongthe various components of the second order optical process are determined by a fewphysical parameters; the radiative damping rate and the modulation amplitude andratc. Further we discuss the relationships between the first and the second order opticalprocesses.
- 社団法人日本物理学会の論文
- 1977-09-15
著者
-
Kubo Ryogo
Department Of Physics Faculty Of Science University Of Tokyo
-
TAKAGAHARA Toshihide
Department of Electronics and Information Science, Kyoto Institute of Technology
-
Hanamura Eiichi
Department Of Applied Physics Faculty Of Engineering University Of Tokyo
-
Hanamura Eiichi
Department Of Applied Physics Faculty Of Engineering The University Of Tokyo
-
Kubo Ryogo
Department Of Physics Faculty Of Science And Technology Keio University
-
Takagahara Toshihide
Department Of Applied Physics Faculty Of Engineering University Of Tokyo
-
Kubo Ryogo
Department of Physics,Faculty of Science,University of Tokyo
-
Hanamura Eiichi
Department of Applied Physics,Faculty of Engineering,University of Tokyo
関連論文
- Long-Time Spin Relaxation in Zero-Field
- Performance Analysis of a Three-Channel Control Architecture for Bilateral Teleoperation with Time Delay
- Nano-optical probing of exciton wave-functions confined in a GaAs quantum dot
- Linear and Non-Linear Optical Responses of a Strongly Coupled Electron-Lattice System
- Photo-Induced Structure Changes
- Dressed State in Solids and Optical Resonance Saturation
- Optical Response of a Randomly Modulated Two-Level Atom
- Band Theoretical Interpretation of Neutron Diffraction Phenomena in Ferromagnetic Metals
- Photon Statistics in a Thick Barrier Coupled Quantum Dot
- Coexistence of Local and Band Characters in the Absorption Spectra of Solids : I. Formulation
- Reversal of the Singularity in the Absorption Spectra of Solids
- Stochastic Theory of Emission Spectrum from Strongly Driven System
- Nonlinear Optical Phenomena with Finite Memory Effects
- Optical Absorption of Molecular Chains with Conformational Disorder
- Second Order Optical Processes in a Localized Electron-Phonon System : -Transient Response-
- Second Order Optical Processes in a Localized Electron-Phonon System : -Stationary Response-
- Stochastic Models of Intermediate State Interaction in Second Order Optical Processes : Transient Response
- Stochastic Models of Intermediate State Interaction in Second Order Optical Processes : Stationary Response. : II
- Stochastic Models of Intermediate State Interaction in Second Order Optical Processes : Stationary Response. : I
- Cyclotron resonance of hot electrons in pure germanium
- Note on the Paramagnetic Susceptibility and the Gyromagnetic Ratio in Metals
- On Impurity Pinning of One-Dimensional Charge Density Waves
- Second Order Optical Process of a Three-Level System in Contact with a Nearly Gaussian-Markoffian Noise Bath
- Generalized Cumulant Expansion Method
- Two-Time Correlation Functions of a System Coupled to a Heat Bath with a Gaussian-Markoffian Interaction
- Time-Dependent Spectrum of a Two-Level System Coupled to a Heat Bath Driven by Pulsed Laser
- Time Evolution of a Quantum System in Contact with a Nearly Gaussian-Markoffian Noise Bath
- Nonlinear Optical Response of Three-Level Atomic System
- Second Order Optical Process of A Randomly Modulated Multi-Level Atom
- Resonant Raman Scattering and Luminescence due to Excitonic Molecule
- Anharmonic Effects on the Vibration Spectrum of the U-Centers in Alkali-Halide Crystals
- Stochastic Theory of Coherent Optical Transients
- Stochastic Theory of Coherent Opitcal Transients.II.Free Induction Decay in Pr^:LaF_3
- Optical Response of Exciton-Phonon System.II.Formulation of Emission Spectrum
- Optical Response of Exciton-Phonon System.III.Resonant Raman Scattering and Luminescence
- Optical Response of Exciton-Phonon System I. : Absorption Spectrum and Urbach-Martienssen Rule
- A General Theory of Magnetic Resonance Absorption
- Statistical Theory of Linear Polymers : V. Paraffine-like Chain
- Electronic Properties of Fine Metallic Particles. : II. Plasma Resonance Absorption
- Note on the Stochastic Theory of Resonance Absorption
- A Note on the Orbital Diamagnetism of Nearly Free Electrons
- Large Elastic Deformation of Rubber
- Wigner Representation of Quantum Operators and Its Applications to Electrons in a Magnetic Field
- Interband Effects on Magnetic Susceptibility. : II. Diamagnetism of Bismuth
- Electrical Conduction in a Narrow Band. I. : Moment Method
- Interband Effect on Magnetic Susceptibility. : I. A Simple Two-Band Model
- Statistical-Mechanical Theory of Irreversible Processes.II. : Response to Thermal Disturbance
- Brownian Motion of Spins
- Quantum Theory of Galvanomagnetic Effect. I. : Basic Considerations
- Stochastic Approach to Undamped Spiking of Lasers
- The Method of Generating Function Applied to Radiative and Non-Radiative Transitions of a Trapped Electron in a Crystal
- 26aWH-8 Quantum dynamics in electron-nuclei coupled spin system in a single quantum dot
- Nonlinear Optical Response of Excitons in Semiconductor Microcavities
- Model Analysis of Undamped Spiking : Stochastic Approach
- Two-Photon Echo and Excited State Photon Echo Methods to Deterlnine the Transverse Relaxation Constants of Excitonic Molecules
- Statistical-Mechanical Theory of Irreversible Processes : I. General Theory and Simple Applications to Magnetic and Conduction Problems
- Resonance Raman Scattering and Luminescence from Highly Excited States
- Dynamics of the Ising Model near the Critical Point. I
- Applicaiton of the Method of Generating Function to Radiative and Non-Radiative Transitions of a Trapped Electron in a Crystal