KVL / Klausuren / MAP 1.HS: 13.04  2.HS: 01.06  Zw.Sem.: 20.07  Beginn WS: 17.10

4020200116 Advanced Optical Sciences      VVZ  

VL
Fr 13-15
 wöch. NEW 15 3'101 (24) Tim Schröder, Sven Ramelow, Markus Krutzik
UE
Mo 11-13
 wöch. NEW 14 1'13 (24) Tim Schröder, Markus Krutzik, Sven Ramelow
SE
Mo 13-15
 wöch. NEW 15 3'101 (24) Tim Schröder, Kurt Busch, Achim Peters, Alejandro Saenz, Sven Ramelow, Markus Krutzik, Francesco Intravaia

Präsenzkurs

Unterrichtssprache
DE
Lern- und Qualifikationsziele
Die Studierenden erwerben vertiefte Kenntnisse wichtiger theoretischer Entwicklungen und Schlüsselexperimente der modernen Optik und sind in der Lage, diese Kenntnisse für die Lösung einschlägiger Probleme zur Anwendung zu bringen.
Voraussetzungen
keine
Gliederung / Themen / Inhalte
Schlüsselexperimente der modernen Optik (z.B. Arbeiten, die zu Nobelpreisen mit direktem Bezug zur Optik geführt haben).Theoretische Grundlagen dieser Schlüsselexperimente.

Part I
The first part of the course introduces single optical and atomic quantum systems. In particular atom-like defects in solid-state materials and their coupling to quantized electromagnetic fields will be introduced. This includes (i) Single Photons & Single Emitters, (ii) Cavity QED in the Weak Coupling Regime, (iii) Diamond Defect Centers as Optical Quantum Probes, (iv) Diamond Defect Centers as Magnetic Quantum Probe, and (v) Quantum Information Processing in Diamond. Focus will be on recent developments and state-of-the-art experiments

Part II
The second part is dedicated to the topic of closing loopholes in Bell-experiments, which is crucially relevant for the interpretation of quantum mechanics. It includes an introduction to the concepts of the EPR-paradox, local-realism and Bell-Inequalities, and gives a brief overview over the key experiments and experimental methods to violate a Bell-Inequality while closing all possible loopholes.

Part III
Ultra-cold atom research led to several Nobel prizes in physics, amongst others, honoring the creation of the Bose-Einstein condensate – A phenomenon described by coherently oscillating atoms which expand with temperatures that correspond to billionths of a degree above absolute zero only. In this part of the lecture, we will study the basics of cold atom technology and discuss why this is an important step forward in our ability to study and control the fundamental building blocks of nature, as well as for driving innovations in metrology, timing and field sensing applications.
Zugeordnete Module
P24.4.c P32
Umfang, Studienpunkte; Modulabschlussprüfung / Leistungsnachweis
6 SWS, 12 SP/ECTS (Arbeitsanteil im Modul für diese Lehrveranstaltung, nicht verbindlich)
Klausur, 120 Minuten, oder mündliche Prüfung, 30 Minuten, und Vorbereitung
Ansprechpartner
Dr. Sven Ramelow, 1'708, sven.ramelow@physik.hu-berlin.de
Moodle link:
http://moodle.hu-berlin.de/course/view.php?id=95693
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