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Advanced experimental physics: Lasers, atomic physics and quantum optics (EV-A)10 ECTS (englische Bezeichnung: Advanced experimental physics: Lasers, atomic physics and quantum optics)
Modulverantwortliche/r: Joachim von Zanthier, Dozenten der experimentellen Physik Lehrende:
Joachim von Zanthier
Startsemester: |
WS 2019/2020 | Dauer: |
1 Semester | Turnus: |
jährlich (WS) |
Präsenzzeit: |
90 Std. | Eigenstudium: |
210 Std. | Sprache: |
Englisch |
Lehrveranstaltungen:
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Advanced Course in Experimental Physics (Lasers, Atomic Physics and Quantum Optics)
(Vorlesung, 4 SWS, Joachim von Zanthier, Di, Do, 12:00 - 14:00, HH)
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Advanced Course in Experimental Physics (Lasers, Atomic Physics and Quantum Optics) (Excercise class)
(Übung, 2 SWS, Joachim von Zanthier, Do, 8:00 - 10:00, SR 01.779, SR 00.732, SRLP 0.179; Mi, 10:00 - 12:00, SRLP 0.179, SR 00.732)
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Advanced Course in Experimental Physics (Lasers, Atomic Physics and Quantum Optics)(Laser exercise lab)(EV-AL)
(Übung, 1 SWS, Anwesenheitspflicht, Joachim von Zanthier, nach Vereinbarung)
Inhalt:
Contents
Fundamental Properties and working scheme of the Laser, applications
Ray transfer matrix analysis, stability criteria for optical resonators
Solutions to the wave equation, complex index of refraction, dispersion
Solution of the paraxial wave equation, Gaussian beams of higher order, properties of
Gaussian beams, Gaussian beams and resonators, resonators as interferometer and
spectrometer
Classical description, semiclassical description, stimulated emission, black body radiation,
interaction of a two-level atom with a monochromatic wave
Maxwell-Bloch-equations, laser operation in equilibrium, rate equations, outcoupled laser
power, relaxation oscillations, micro-lasers, laser noise (Schawlow-Townes-Limit), generation
and measurement of ultrashort pulses
Gas lasers, solid state lasers, vibronic lasers, laser frequency analysis and stabilization
Spectral lines + -profiles, broadening mechanisms, doppler-free spectroscopy
Doppler cooling, magneto-otical trap, trapping of single atoms, Bose-Einstein-condensation
Introduction to quantum optics
Hanbury-Brown-Twiss experiment, quantum nature of light, photon correlations, photon
statistics, examples of non-classical light, bunching und antibunching of photons, resonance
fluorescence
Lernziele und Kompetenzen:
Students
explain and analyze advanced topics of lasers, atomic physics and quantum optics as outlined in the table of contents
apply the associated physical concepts to specific problems using appropriate methods
Bemerkung:
May be applied to specialisation 'Optical sciences' in the physics master program starting winter term 2017/18.
Verwendbarkeit des Moduls / Einpassung in den Musterstudienplan: Das Modul ist im Kontext der folgenden Studienfächer/Vertiefungsrichtungen verwendbar:
- Physics (Master of Science): ab 1. Semester
(Po-Vers. 2015s | NatFak | Physics (Master of Science) | Gesamtkonto | Advanced experimental physics)
- Physics (Master of Science)
(Po-Vers. 2018w | NatFak | Physics (Master of Science) | Gesamtkonto | Advanced experimental physics)
Studien-/Prüfungsleistungen:
Advanced Course in Experimental Physics: Lasers, Atomic Physics and Quantum Optics (Prüfungsnummer: 69411)
(englischer Titel: Advanced Course in Experimental Physics: Lasers, Atomic Physics and Quantum Optics)
- Prüfungsleistung, Klausur, Dauer (in Minuten): 120, benotet, 10 ECTS
- Anteil an der Berechnung der Modulnote: 100.0 %
- Prüfungssprache: Englisch
- Erstablegung: WS 2019/2020, 1. Wdh.: WS 2019/2020 (nur für Wiederholer)
1. Prüfer: | Joachim von Zanthier |
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UnivIS ist ein Produkt der Config eG, Buckenhof |
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