| Prerequisites and co-requisites |
|
| Language of instruction |
English |
| Type |
Elective |
| Level of Course |
Bachelor's |
| Lecturer |
Asst. Prof. Çağdaş ALLAHVERDİ |
| Mode of Delivery |
Face to Face |
| Suggested Subject |
|
| Professional practise ( internship ) |
None |
| Objectives of the Course |
Teaching modern physics topics |
| Contents of the Course |
Special Relativity Relative Mass and Energy Electromagnetic waves, Luminescence, Photoelectrical phenomena X-rays, Compton phenomenon, Double formation, Photon and mass attraction Debugli waves, Representation of a subgraph, Diffraction of particles Applications of the Particle, Uncertainty and Uncertainty principle in the box Atom, Electron orbitals And atomic spectra, Borh atom Midterm Exam Energy Levels and Spectra, Correspondence Principle Movement of the Chord, Atomic Induction and Laser Wave Equation, Time dependent Shcödinger Equation and Expected Values Time Independent Shcödinger Equation and Applications Hydrogen Atom Quantum Theory Hydrogen Atom Quantum Theory Multiple Electron Atoms |
| # |
Learning Outcomes |
| 1 |
Defines the basic concepts of relativity. |
| 2 |
Explains the basic concepts of relativity in classical physics. |
| 3 |
Perceive how basic concepts change in different observation frames. |
| 4 |
Explains the electromagnetic wave is generated from energy packets (photons). |
| 5 |
Analyzes experiments that reveal wave and particle properties of light. |
| 6 |
Recognizes atomic models and atomic spectra. |
| 7 |
Defines theories of single-electron and multi-electron atoms. |
| 8 |
Describes quantum mechanically the physical phenomena at atomic dimension. |
| # |
Subjects |
Teaching Methods and Technics |
| 1 |
Special Relativity |
Lecture |
| 2 |
Relative Mass and Energy |
Lecture |
| 3 |
Electromagnetic waves, Luminescence, Photoelectric effect |
Lecture |
| 4 |
X-rays, compton phenomenon, dual formation, photon and mass attraction |
Lecture |
| 5 |
De broglie waves, Representation of a splatter, Diffraction of particles |
Lecture |
| 6 |
Particle in the box, the applications of uncertainty principle and uncertainty principle |
Lecture |
| 7 |
Midterm |
|
| 8 |
Atoms, electron orbits and atomic spectra, Bohr atoms |
Lecture |
| 9 |
Energy Levels and Spectra, Counterpart finding principle |
Lecture |
| 10 |
The movement of the core, Atomic stimulation and Laser |
Lecture |
| 11 |
Wave equation, Time dependent shcödinger equation and expected values |
Lecture |
| 12 |
Time independent Shcödinger Equation and its applications |
Lecture |
| 13 |
Quantum Theory of Hydrogen Atom |
Lecture |
| 14 |
Quantum Theory of Hydrogen Atom |
Lecture |
| 15 |
Atoms with many electrons |
Lecture |
| 16 |
Final Exam |
|
| # |
Learning Outcomes |
Program Outcomes |
Method of Assessment |
| 1 |
Defines the basic concepts of relativity. |
1 |
1͵2 |
| 2 |
Explains the basic concepts of relativity in classical physics. |
1 |
1͵2 |
| 3 |
Perceive how basic concepts change in different observation frames. |
1 |
1͵2 |
| 4 |
Explains the electromagnetic wave is generated from energy packets (photons). |
1 |
1͵2 |
| 5 |
Analyzes experiments that reveal wave and particle properties of light. |
1 |
1͵2 |
| 6 |
Recognizes atomic models and atomic spectra. |
1 |
1͵2 |
| 7 |
Defines theories of single-electron and multi-electron atoms. |
1 |
1͵2 |
| 8 |
Describes quantum mechanically the physical phenomena at atomic dimension. |
1 |
1͵2 |
