Course Objectives
At the completion of this course, students will be able to:
1) Understand the relation about photon among energy, wavelength and momentum.
2) Understand Schrodinger equation and handling of the wave function.
3) Understand Pauli's exclusion principle and Fermi - Dirac's distribution function.
Rubric
| Ideal Level of Achievement (Very Good) | Standard Level of Achievement (Good) | Unacceptable Level of Achievement (Fail) |
| Evaluation 1 | Can understand the properties of the photon properly and can solve an applied problem. | Can understand the properties of the photon and can solve a basic problem. | Cannot understand the properties of the photon and cannot solve a basic problem. |
| Evaluation 2 | Can understand Schrodinger equation and a wave function properly and can solve an applied problem. | Can understand Schrodinger equation and a wave function and can solve a basic problem. | Cannot understand Schrodinger equation and a wave function and cannot solve a basic problem. |
| Evaluation 3 | Can understand Pauli's exclusion principle and Fermi-Dirac's distribution function properly and can solve an applied problem. | Can understand Pauli's exclusion principle and Fermi-Dirac's distribution function and can solve a basic problem. | Cannot understand Pauli's exclusion principle and Fermi-Dirac's distribution function and cannot solve a basic problem. |
Assigned Department Objectives
JABEE B1
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ディプロマポリシー 3
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Teaching Method
Outline:
Engineering is based on physics. It is important to understand essence of engineering based on physics because engineers should be able to adapt it to unknown fields of study, and today’s technological change and diversity. In this course of lectures, we will study about basics quantum mechanics which supports modern physics.
Quantum mechanics supports today’s high-technique science in many fields. It’s a professional study, and the concept may be necessary for engineers. The purpose of this course of lectures is to understand the basic of quantum mechanics, and structure and property of an atom and a material related to quantum mechanics.
Style:
Lectures by teachers alone are conducted.
Notice:
The recognition of credit requires 60 points or more rating. A person who has a rating of less than 60 points may be subjected to an approval test by request. As the result of the approval test, the evaluation is made
to be 60 points in the person who the mastery of the unit is recognized.
Course Plan
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|
|
Theme |
Goals |
| 2nd Semester |
| 3rd Quarter |
| 1st |
Property of the light, black body radiation and Planck's quantum hypothesis |
1) Can explain wavelength, frequency and speed of light.
2) Can derive Planck's formula.
3) Can explain Planck's quantum hypothesis.
|
| 2nd |
Photoelectric effect, Compton effect and particle characteristics of light |
1) Can explain photoelectric effect and Compton effect.
2) Can explain that a photon has energy and a momentum.
3) Can solve problems about photoelectric effect and Compton effect.
|
| 3rd |
Atomic spectrum, Rydberg's formula and quantum condition of Bohr |
1) Can explain atomic spectrum and Rydberg's formula.
2) Can explain a quantum condition of Bohr.
3) Can derive Rydberg's formula using a quantum condition of Bohr.
|
| 4th |
Waviness of electron, de Broglie wabe and Schrodinger equation |
1) Can explain waviness of electron and de Broglie wabe.
2) Can derive Schrodinger equation using classic wave equation and de Broglie's formula.
|
| 5th |
One-dimensional well potential problem
|
Can find the wave function and the probability density function on one-dimensional well potential problem using boudary condition and normalization condition.
|
| 6th |
Expected value and fluctuation of position |
Can find expected value and fluctuation of position on one-dimensinal well potential problem.
|
| 7th |
Midterm exam |
|
| 8th |
Expected value, fluctuation of momentum and uncertainty principle of Heisenberg |
1) Can find expected value and fluctuation of momentum on one-dimensinal well potential problem.
2) Can explain uncertainty principle of Heisenberg.
3) Can prove uncertainty relation on one-dimensional well potential problem.
|
| 4th Quarter |
| 9th |
Schrodinger equation for applying to hydrogen atom |
1) Can apply Schrodinger equation to hydrogen atom.
2) Can solve Schrodinger equation on hydrogen atom.
|
| 10th |
Four quantum numbers and Pauli's exclusion principle |
1) Can explain four quantum numbers and their propaties.
2) Can explain Pauli's exlcusion principle.
|
| 11th |
Energy level being divided and an energy band being formed in gas molecules and solid molecules, according to Pauli's exlusion principle |
1) Can explain division of energy level.
2) Can explain each level and its characteristics in energy band.
|
| 12th |
Distinction of conductor, semiconductor and insulator
Sate density, Fermi-Dirac distribution and electron density |
1) Can expain the distinction of conductor, semiconductor and insulator from the viewpoint of energy band.
2) Can understand state density and Fermi-Dirac distribution and can derive electron density.
|
| 13th |
Intrinsic semiconductor and impurity semiconductor
Constitution and property of n-type semiconductor and the p-type semiconductor |
Can explain constitution and a property of n-type semiconductor and the p-type semiconductor.
|
| 14th |
Problem exercise |
|
| 15th |
Final exam |
|
| 16th |
Grading confirmation, question evaluation questionnaire |
|
Evaluation Method and Weight (%)
| Examination | Presentation | Mutual Evaluations between students | Behavior | Portfolio | Other | Total |
| Subtotal | 80 | 0 | 0 | 0 | 20 | 0 | 100 |
| Basic Ability | 40 | 0 | 0 | 0 | 10 | 0 | 50 |
| Technical Ability | 40 | 0 | 0 | 0 | 10 | 0 | 50 |