Course Manual LMW
Light-Matter-Interaction
PDF Course Catalog Deutsche Version: LMW
Version: 1 | Last Change: 29.09.2019 18:32 | Draft: 0 | Status: vom verantwortlichen Dozent freigegeben
| Long name | Light-Matter-Interaction |
|---|---|
| Approving CModule | LMW_BaET, LMW_BaOPT |
| Responsible |
Prof. Dr. Uwe Oberheide
Professor Fakultät IME |
| Valid from | winter semester 2022/23 |
| Level | Bachelor |
| Semester in the year | winter semester |
| Duration | Semester |
| Hours in self-study | 78 |
| ECTS | 5 |
| Professors |
Prof. Dr. Uwe Oberheide
Professor Fakultät IME |
| Requirements | Physics: oscillator, wave propagation, index of refraction Material science: electrical material properties (permeability, band gap) electrical dipole Mathematics: linear algebra (vector / matrix calculations) Optics: radiometric and photometric properties, geometrical optics, wave optics |
| Language | German |
| Separate final exam | Yes |
Literature
| Pedrotti - Optik für Ingenieure, Springer |
| Saleh, Teich - Grundlagen der Photonik, Wiley-VCH |
Final exam
| Details |
taxonomy levels understanding and application: Description of elementary applications and interaction processes in an idealized application environment taxonomy level analyzing: Selection of suitable optical components and processes based on real application cases |
|---|---|
| Minimum standard | 50 % of the questions correctly answered |
| Exam Type | EN mündliche Prüfung, strukturierte Befragung |
Learning goals
| Goal type | Description |
|---|---|
| Knowledge | Propagation of electromagnetic waves: - Lorentz oscillator - permeability Interaction processes of light and matter: - (complex) refractive index - absorption - scattering - luminescence Generation of polarized light Birefringence - polarization - phase plates Energy levels: - atomic spectra - fluorescence / phosphorescence - band structure Detection of electromagnetic radiation: - semiconductor detectors - measuring systems for spatial distributions Light-induced material processing: - lithography - ablation Photonic crystals |
| Skills | Recognizing and transfer of analogies of known physical processes (excited, damped oscillator -> Lorentz oscillator) Transfer of idealized systems to real systems and derivation of the qualitative behavior of the system Describing and explaining relationships between quantities (absorption / refractive index) and transferring them to real materials Analyze technical applications and questions, break them down into individual processes and solve them via known light-matter-interaction processes. |
Expenditure classroom teaching
| Type | Attendance (h/Wk.) |
|---|---|
| Lecture | 3 |
| Exercises (whole course) | 1 |
| Exercises (shared course) | 0 |
| Tutorial (voluntary) | 0 |
Special requirements
| none |
| Accompanying material |
Presentation slides for the lecture Links to Internet resources with basic information |
|---|---|
| Separate exam | No |
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