Course title | |||||
原子分子物理 [Atomic and Molecular Physics] | |||||
Course category | technology speciality courses,ets. | Requirement | Credit | 2 | |
Department | Year | 4~4 | Semester | 1st | |
Course type | 1st | Course code | 024603 | ||
Instructor(s) | |||||
鵜飼 正敏 [UKAI Masatoshi] | |||||
Facility affiliation | Faculty of Engineering | Office | Email address |
Course description |
This course aims to apply the theoretical bases of Quantum Mechanics, as well as Classical Mechanics, to understand the several phenomena in atomic and moleculer phyiscs. Verious finding and understanding on atoms and molecules have been indispensable to the development and progress of basic theories in science, such as quantum mechanics and statistical mechanics. Atoms and molecules are not the rigorously smallest particles by the smallest units showing the properties of materials. Due to these reasons we study quantum mechanically the basis of atoms and molecules in order to obtain appropriate image of nano-scale world. In the case of negligible uncertainty of particles involved in chemical raction dynamics, we confirm that classical mechanics can also give appropriate view point of understanding. |
Expected Learning |
1) To become able to understand atomic internal states and able to explain their properties. 2) To become able to explain, at least qualitatively, the internal structures of multi-electron atoms. 3) To become able to explain the origin of chemical bonds and their characteristice difference. 4) To became able to understand conceptually the interaction between atoms and molecules and the chemical reactions. See the Curriculum maps. |
Course schedule |
(1st class) Introduction. (2nd class) Revision of one electron atoms. (3rd class) Two electron atoms; electron spin and operators. (4th class) Eigen energies and wave functions of two electron atoms; basic concept and independent particle model. (5th class) Eigen energies and wave functions of two electron atoms; approximations. (6th class) Electronic structures of multi-electron atoms. (7th class) Internal structures of diatomic molecules; electronic coupled equation and Born-Oppenheimer approximation. (8th class) Potential energy curves of diatomic molecules and the internal motion on them. (9th class) Electronic states, symmetry properties, and avoided crossing of diatomic molecules. (10th class) Chemical bond; hydrogen ion. (11th class) Chemical bond; hydrogen molecules. (12th class) Electronic structures of more complex diatomic molecules. (13th class) Inter-atomic/molecular interaction and chemical reactions; cross sections and reaction rate. (14th class) Inter-atomic/molecular interaction and chemical reactions; motion of potential curves(surfaces) and deflection function. (15th class) Inter-atomic/molecular interaction and chemical reactions, classical theory of scattering and its cross section. |
Prerequisites |
Quantum mechanics I and II are assumed to be completed. Internatl structures od atoms and molecules are treated quantum mechnically. The interaction of atoms and molecules and the chemical reactions are treated classically. The students in the group of quatum systems and meterial physics are highly recommended to join. Students are expected to have the standard amount of time to prepare for and review the lecture as specified by the University. |
Required Text(s) and Materials |
Not specified. Summary of lecture notes will be provided. |
References |
1) B.H.Bransden and C.J.Joachain, Physics of atoms amd molecules (Pearson Education, 2nd edition). 2) R.D.Levine, Molecular reaction dynamics(Cambridge). |
Assessment/Grading |
(1) Quizzes at the begining and at the end of every lecture. (2) Examination at the end of semester. The weight of evaluation of (1) to (2) is approximately 1 to 3. |
Message from instructor(s) |
Keep your brains operating appropriately! |
Course keywords |
Quantum Mechnics, Atoms and Molecules, and Chemical Reactions. |
Office hours |
Welcome at office. Need appointments beforehand by Email. Office: Bld. No.4, rm.510. Email: ukai3 |
Remarks 1 |
Remarks 2 |
Related URL |
Lecture Language |
Japanese |
Language Subject |
Last update |
3/18/2019 3:18:05 PM |