phy612 - Advanced Physics I (Vollständige Modulbeschreibung)
Modulbezeichnung | Advanced Physics I |
Modulkürzel | phy612 |
Kreditpunkte | 6.0 KP |
Workload | 180 h |
Einrichtungsverzeichnis | Institut für Physik |
Verwendbarkeit des Moduls |
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Zuständige Personen |
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Teilnahmevoraussetzungen | |
Kompetenzziele | Fluiddynamik Fouriertechniken in der Physik The students know the definition of the Fourier-Transformation (FT) and learn about explicit examples. They know the properties and theorems of the FT, are able to apply these and describe physical processes both in time and frequency domain. They gain deep insights about physical processes analyzing the frequency domain and are able to utilize Fourier techniques solving physical problems, e.g. finding solutions of the time dependent Schrödinger equation. In addition, they learn about examples of the current english physical literature. Photonics Starting from basics, the module yields advanced knowledge of the physics of lasers, of optical radiation with matter, optoelectronic principles and components as, e.g. laser beams, different laser types, light emitters, detectors, modulators. The students acquire skills in working with lasers and optoelectronic components. |
Modulinhalte | Fluiddynamics I Base equations: Navier-Stokes equations, continuity equation, Bernoulli’s law; Vortex and energy equations laminar flow and analysis of stability exact solutions and applications Fluiddynamics II Reynolds' turbulence Closure problems and approaches models of turbulence, principles of CFD, Cascade models – stochastic models Fouriertechniken in der Physik Motivation: Applications of the FT in physics. Examples for Fourier paires, properties of the FT: symmetries, important theorems, shifting, differentiation, convolution theorem, uncertainty relation. Examples concerning the convolution theorem: frequency comb, Hilbert transformation, autocorrelation function. Methods of the time/frequency analysis and Wigner distribution. FT in higher dimensions: tomography. Discrete FT, sampling theorem. Applications in quantum mechanics. Photonics Fundamentals of lasers (optical gain, optical resonator, laser beams), laser types, laser safety; electronic bandstructures in matter, semiconductor junctions, radiation laws, light emitting diodes, photodetectors, solar cells. |
Literaturempfehlungen |
G. K. Batchelor: An introduction to fluid dynamics. Cambridge University Press, Cambridge, 2002 U. Frisch: Turbulence: the legacy of A. N. Kolmogorov. Cambridge University Press, Cambridge, 2001 J. Mathieu, J. Scott: An introduction to turbulent flow. Cam- bridge University Press, Cambridge, 2000 P.A. Davidson: turbulence Oxford 2004
T. Butz: „Fouriertransformation für Fußgänger“, Vieweg+Teubner, 7. Auflage (2011) D. W. Kammler: „A First Course in Fourier Analysis”, Cam- bridge University Press (2008) M. Wollenhaupt, A. Assion and T. Baumert: “Springer Handbook of Lasers and Optics”, Springer, Chapter 12, 2. Auflage (2012) L. Cohen: „Time Frequency Analysis“, Prentice Hall (1995) Weitere spezielle Literatur wird in der Vorlesung bekannt gegeben.
F. Träger (ed.), Handbook of Laser and Optics, 2nd. ed. 2012, Springer Verlag, Berlin Saleh, Teich: Fundamentals of Photonics, John Wiley & Sons Ebeling: Integrierte Optoelektronik, Springer Verlag Original literature according indication during course |
Links | |
Unterrichtsprachen | Deutsch, Englisch |
Dauer in Semestern | 1 Semester |
Angebotsrhythmus Modul | jährlich |
Aufnahmekapazität Modul | unbegrenzt |
Lehr-/Lernform | Lecture and exercise |
Prüfung | Prüfungszeiten | Prüfungsform |
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Gesamtmodul | 1 exam or 1 presentation or 1 oral examination or 1 chore |
Lehrveranstaltungsform | Seminar |
Angebotsrhythmus |