Physik-Department, TUM | LV 0000000935 im WS 2022/3

Basisdaten

LV-Art

Vorlesung

Umfang

2 SWS

betreuende Organisation

Experimentelle Halbleiterphysik

Dozent(inn)en

Martin Brandt
Dominik Bucher
Hans-Gregor Hübl

Termine

Mi, 10:00–12:00, ZNN 0.001

iCalendar

	Datum und Zeit	Raum und Anmerkung
	Mi, 19.10.2022, 10:00–12:00	Am Coulombwall 4a
	Mi, 26.10.2022, 10:00–12:00	Am Coulombwall 4a
	Mi, 09.11.2022, 10:00–12:00	Am Coulombwall 4a
	Mi, 16.11.2022, 10:00–12:00	Am Coulombwall 4a
	Mi, 23.11.2022, 10:00–12:00	Am Coulombwall 4a
	Mi, 30.11.2022, 10:00–12:00	Am Coulombwall 4a
	Mi, 07.12.2022, 10:00–12:00	Am Coulombwall 4a
	Mi, 14.12.2022, 10:00–12:00	Am Coulombwall 4a
	Mi, 21.12.2022, 10:00–12:00	Am Coulombwall 4a
	Mi, 11.01.2023, 10:00–12:00	Am Coulombwall 4a
	Mi, 18.01.2023, 10:00–12:00	Am Coulombwall 4a
	Mi, 25.01.2023, 10:00–12:00	Am Coulombwall 4a
	Mi, 01.02.2023, 10:00–12:00	Am Coulombwall 4a
	Mi, 08.02.2023, 10:00–12:00	Am Coulombwall 4a

Zuordnung zu Modulen

PH2317: Quantensensorik / Quantum Sensing
Dieses Modul ist in den folgenden Katalogen enthalten:
- Spezifischer Spezialfachkatalog Physik der kondensierten Materie
- Spezifischer Spezialfachkatalog Applied and Engineering Physics
- Fokussierungsrichtung Experimentelle Quantenwissenschaften & -technologien im M.Sc. Quantum Science & Technology
- Komplementärer Spezialfachkatalog Kern-, Teilchen- und Astrophysik
- Komplementärer Spezialfachkatalog Biophysik

weitere Informationen

Lehrveranstaltungen sind neben Prüfungen Bausteine von Modulen. Beachten Sie daher, dass Sie Informationen zu den Lehrinhalten und insbesondere zu Prüfungs- und Studienleistungen in der Regel nur auf Modulebene erhalten können (siehe Abschnitt "Zuordnung zu Modulen" oben).

ergänzende Hinweise	Amongst the various quantum technologies being developed, quantum sensing stands out: It has become a real-world application operating at room temperature and is being used to measure magnetic and electric fields, temperature, pressure and, yes, gravitation. This module will introduce you to the basic physics behind this exciting technology, will demonstrate a specific realisation based on so-called color centers in considerable detail and will discuss how to push the limits of quantum sensing. We will start by reviewing quantum mechanical two-level systems and their representation in the Bloch sphere, spins and their dynamics including relaxation and decoherence as well as magnetic resonance and the pulse sequences used to study it. We will introduce the nitrogen-vacancy complex in diamond and will learn how to measure dc and ac magnetometry using this atomic scale sensor to realise, e.g., NMR spectrometers capable of analysing minute samples. In the second part of the module, we will take a step back and look at the fundamentals of the quantum mechanical measurements process including the standard quantum limit, quantum non-demolition measurements as well as squeezed states and present examples from solid state physics for the field of quantum or cavity optomechanics as well as spin ensembles where these concepts are put to practice.
Links	E-Learning-Kurs (z. B. Moodle) TUMonline-Eintrag TUMonline-Anmeldeverfahren

ergänzende Hinweise

Amongst the various quantum technologies being developed, quantum sensing stands out: It has become a real-world application operating at room temperature and is being used to measure magnetic and electric fields, temperature, pressure and, yes, gravitation. This module will introduce you to the basic physics behind this exciting technology, will demonstrate a specific realisation based on so-called color centers in considerable detail and will discuss how to push the limits of quantum sensing. We will start by reviewing quantum mechanical two-level systems and their representation in the Bloch sphere, spins and their dynamics including relaxation and decoherence as well as magnetic resonance and the pulse sequences used to study it. We will introduce the nitrogen-vacancy complex in diamond and will learn how to measure dc and ac magnetometry using this atomic scale sensor to realise, e.g., NMR spectrometers capable of analysing minute samples. In the second part of the module, we will take a step back and look at the fundamentals of the quantum mechanical measurements process including the standard quantum limit, quantum non-demolition measurements as well as squeezed states and present examples from solid state physics for the field of quantum or cavity optomechanics as well as spin ensembles where these concepts are put to practice.

Links

E-Learning-Kurs (z. B. Moodle)
TUMonline-Eintrag
TUMonline-Anmeldeverfahren

Gleiche Lehrveranstaltungen (z. B. in anderen Semestern)

Semester	Titel	Dozent(en)	Termine
WS 2023/4	Quantum Sensing	Brandt, M. Bucher, D. Hübl, H.	Mi, 10:00–12:00, ZNN 0.001
WS 2021/2	Quantum Sensing	Brandt, M. Hübl, H. Mitwirkende: Bucher, D.	Do, 10:00–12:00, ZNN 0.001

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Quantensensorik
Quantum Sensing

Lehrveranstaltung 0000000935 im WS 2022/3

Basisdaten

Zuordnung zu Modulen

weitere Informationen

Gleiche Lehrveranstaltungen (z. B. in anderen Semestern)

QuantensensorikQuantum Sensing

Lehrveranstaltung 0000000935 im WS 2022/3

Basisdaten

Zuordnung zu Modulen

weitere Informationen

Gleiche Lehrveranstaltungen (z. B. in anderen Semestern)

Quantensensorik
Quantum Sensing