Lehrinhalte
[b]Thermodynamics[/b]
[list]
[*]Fundamentals
[*]First law of thermodynamics
[*]Phase transitions and cyclic processes
[/list]
[b]Electromagnetic fields and waves[/b]
[list]
[*]Electric field
[*]Magnetic field
[*]Matter in fields
[*]Time-dependent fields
[*]Electromagnetic radiation
[/list]
[b]Optics[/b]
[list]
[*]Geometrical optics
[*]Wave optics
[/list]
[b]Quantum physics[/b]
[list]
[*]Matter and light quanta
[*]Quantum optics and lasers
[*]Particle-wave duality
[/list]
Literatur
The main suggested text for the lecture is
[b]E. Hering, R. Martin, M. Stohrer,
Physik für Ingenieure[/b]
Springer-Verlag, Berlin und Heidelberg, 11th edition
Beyond this text, numerous textbooks on fundamental physics may be used, e.g.:
[list]
[*]Giancoli: Physics for Scientists & Engineers
[*]Halliday, Resnick, Walker: Fundamentals of Physics
[*]Tipler, Mosca: Physics for Scientists and Engineers
[/list]
Voraussetzungen
Knowledge, skills, and competences acquired in the Module "Physik für ET I"
Erwartete Teilnehmerzahl
250
Further Grading Information
Successful submission of solved homework problems qualifies for an up to 0.4 point grade bonus.
Official Course Description
cf. course description of the Dept. of Electrical Engineering and Information Technology
Online-Angebote
Moodle
[b]Thermodynamics[/b]
[list]
[*]Fundamentals
[*]First law of thermodynamics
[*]Phase transitions and cyclic processes
[/list]
[b]Electromagnetic fields and waves[/b]
[list]
[*]Electric field
[*]Magnetic field
[*]Matter in fields
[*]Time-dependent fields
[*]Electromagnetic radiation
[/list]
[b]Optics[/b]
[list]
[*]Geometrical optics
[*]Wave optics
[/list]
[b]Quantum physics[/b]
[list]
[*]Matter and light quanta
[*]Quantum optics and lasers
[*]Particle-wave duality
[/list]
Literatur
The main suggested text for the lecture is
[b]E. Hering, R. Martin, M. Stohrer,
Physik für Ingenieure[/b]
Springer-Verlag, Berlin und Heidelberg, 11th edition
Beyond this text, numerous textbooks on fundamental physics may be used, e.g.:
[list]
[*]Giancoli: Physics for Scientists & Engineers
[*]Halliday, Resnick, Walker: Fundamentals of Physics
[*]Tipler, Mosca: Physics for Scientists and Engineers
[/list]
Voraussetzungen
Knowledge, skills, and competences acquired in the Module "Physik für ET I"
Erwartete Teilnehmerzahl
250
Further Grading Information
Successful submission of solved homework problems qualifies for an up to 0.4 point grade bonus.
Official Course Description
cf. course description of the Dept. of Electrical Engineering and Information Technology
Online-Angebote
Moodle
- Lehrende: ScheitHeiko
Semester: ST 2019
Lehrinhalte
Rough outline of the lecture:
1. Introduction
2. Static properties of atomic nuclei
3. Introduction to particle physics
4. Phenomenology of nuclear force
5. Concepts of simple models for nuclear structure
6. Radioactive decay
7. Nuclear astrophysics (if time allows)
Literatur
Selection of textbooks:
[list]
[*]Demtröder, Experimentalphysik 4
[*]Henley, Garcia, Subatomic Physics
[*]Krane, Introductory Nuclear Physics
[*]Mayer-Kuckuk, Kernphysik
[*]Povh, Rith, Scholz, Zetsche, Teilchen und Kerne
[/list]
Script (in German) will be supplied.
Voraussetzungen
recommended:
Quantum mechanics (Theor. Physics II)
Physics I-IV (Mechanics, Thermodynamics, Elektrodynamics, Relativistic Mechanics, Atomistic physics)
Kernphysik-Versuche aus dem Grundpraktikum
German language
Erwartete Teilnehmerzahl
40-50
Further Grading Information
Exam: oral examination 30 Min.
A grade bonus can be obtained through active participation in the exercises.
Official Course Description
Students
[list]
[*]know concepts, phenomena, and notions of nuclear physics as well as examples for nuclear applications,
[*]are capable of understanding nuclear models and formulating a mathematical ansatz for nuclear-physics problems,
[*]and are competent in solving problems with respect to nuclear and particle physics, communicating the results, and estimating the accuarcy of their analyses.
[/list]
Online-Angebote
moodle
Rough outline of the lecture:
1. Introduction
2. Static properties of atomic nuclei
3. Introduction to particle physics
4. Phenomenology of nuclear force
5. Concepts of simple models for nuclear structure
6. Radioactive decay
7. Nuclear astrophysics (if time allows)
Literatur
Selection of textbooks:
[list]
[*]Demtröder, Experimentalphysik 4
[*]Henley, Garcia, Subatomic Physics
[*]Krane, Introductory Nuclear Physics
[*]Mayer-Kuckuk, Kernphysik
[*]Povh, Rith, Scholz, Zetsche, Teilchen und Kerne
[/list]
Script (in German) will be supplied.
Voraussetzungen
recommended:
Quantum mechanics (Theor. Physics II)
Physics I-IV (Mechanics, Thermodynamics, Elektrodynamics, Relativistic Mechanics, Atomistic physics)
Kernphysik-Versuche aus dem Grundpraktikum
German language
Erwartete Teilnehmerzahl
40-50
Further Grading Information
Exam: oral examination 30 Min.
A grade bonus can be obtained through active participation in the exercises.
Official Course Description
Students
[list]
[*]know concepts, phenomena, and notions of nuclear physics as well as examples for nuclear applications,
[*]are capable of understanding nuclear models and formulating a mathematical ansatz for nuclear-physics problems,
[*]and are competent in solving problems with respect to nuclear and particle physics, communicating the results, and estimating the accuarcy of their analyses.
[/list]
Online-Angebote
moodle
- Lehrende: AumannThomas
- Lehrende: KröllThorsten
- Lehrende: (TU-ID gelöscht)Gelöschter User
- Lehrende: (TU-ID gelöscht)Gelöschter User
Semester: ST 2019