| Course title | |||||
| 量子光学 [Quantum Optics] | |||||
| Course category | courses for master's programs | Requirement | Credit | 2 | |
| Department | Year | ~ | Semester | Fall | |
| Course type | Fall | Course code | 1060403 | ||
| Instructor(s) | |||||
| 室尾 和之 [MUROO Kazuyuki] | |||||
| Facility affiliation | Faculty of Engineering | Office | Email address | ||
| Course description |
| Interaction between light and matters is one of the most basic and important issues, in the region of the phenomena, emission and absorption of light and nonlinear optical processes, and is fundamental in the region of optical science, such as spectroscopy, optical property and laser physics. |
| Expected Learning |
| The aim of this course is to understand interaction between light and matters, based on the classical oscillator model, semi-classical model and full quantum theory. |
| Course schedule |
|
Week 1: Introduction to quantum optics Week 2: Emission of light, Einstein model, A and B coefficients Week 3: Electric dipole radiation and mechanical oscillator model of electric dipole (Lorentz model) Forced oscillation, electric dipole moment and polarization, complex electric susceptibility Week 4: Propagation of electromagnetic wave complex susceptibility and refraction and extinction coefficient, absorption and dispersion, energy transportation between electromagnetic wave and electric dipole Week 5: Coherent excitation of electric dipoles by electromagnetic wave Week 6: Semi-classical theory of interaction between light and materials time-dependent perturbation and its successive approximation solution, exact solution Week 7: Absorption and emission of light expectation value of electric polarization, Rabi-oscillation and introduction of damping Week 8: Full quantum theory of interaction between light and matters transition from semi-classical theory to full quantum theory Week 9: Vector potential and Coulomb gauge Vector potential and Coulomb gauge of electromagnetic wave Week 10: Mode of wave and associated harmonic oscillator Wave and Fourier transformation, mode, harmonic oscillator Week 11: Quantization of harmonic oscillation Quantization based on linear algebra of harmonic oscillator Week 12: Algebraic properties of creation, destruction and number operators Quantization of harmonic oscillator, energy eigenvalue and Shrodinger equation Week 13: Quantized electromagnetic wave associated with quantized harmonic oscillator Week 14: Property of quantized electromagnetic wave: photon Week 15: Full quantum theory of interaction between light and matters Rigorous derivation of Einstein A and B coefficient based on full quantum theory, non-classical photon states |
| Prerequisites |
| Electromagnetism, Quantum electronics, Photonics, Oscillation and wave |
| Required Text(s) and Materials |
| References |
|
R. Loudon, The Quantum Theory of Light, Clarendon Press. A. Corney, Atomic and Laser Spectroscopy, Clarendon Press. J.N.Dodd, Atoms and Light Interaction, Plenum Press. 霜田光一,レーザー物理入門,岩波書店 山本学, プラズマの分光計測,学会出版センター |
| Assessment/Grading |
| Message from instructor(s) |
| Interaction between light and matters, classical oscillator model, Lorentz model, semi-classical model, Full quantum theory, second quantization, creation and destruction operators |
| Course keywords |
| Office hours |
| Remarks 1 |
| Remarks 2 |
| Related URL |
| Lecture Language |
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| Last update |
| 3/22/2017 9:41:05 AM |