Physik-Department, TUM | LV 0000000774 im WS 2023/4

Basisdaten

LV-Art

Vorlesung

Umfang

2 SWS

betreuende Organisation

Quantennetzwerke

Dozent(inn)en

Andreas Reiserer

Termine

Mi, 10:00–12:00, PH II 127

iCalendar

	Datum und Zeit	Raum und Anmerkung
	Mi, 18.10.2023, 10:00–12:00	Am Coulombwall 2
	Mi, 25.10.2023, 10:00–12:00	Am Coulombwall 2
	Mi, 08.11.2023, 10:00–12:00	Am Coulombwall 2
	Mi, 22.11.2023, 10:00–12:00	Am Coulombwall 2
	Mi, 29.11.2023, 10:00–12:00	Am Coulombwall 2
	Mi, 06.12.2023, 10:00–12:00	Am Coulombwall 2
	Mi, 13.12.2023, 10:00–12:00	Am Coulombwall 2
	Mi, 20.12.2023, 10:00–12:00	Am Coulombwall 2
	Mi, 10.01.2024, 10:00–12:00	Am Coulombwall 2
	Mi, 17.01.2024, 10:00–12:00	Am Coulombwall 2
	Mi, 24.01.2024, 10:00–12:00	Am Coulombwall 2
	Mi, 31.01.2024, 10:00–12:00	Am Coulombwall 2
	Mi, 07.02.2024, 10:00–12:00	Am Coulombwall 2

Zuordnung zu Modulen

PH2263: Quantentechnologie / Quantum Technology
Dieses Modul ist in den folgenden Katalogen enthalten:
- Spezifischer Spezialfachkatalog Physik der kondensierten Materie
- Spezifischer Spezialfachkatalog Applied and Engineering Physics
- 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	Quantum theory was originally formulated as a statistical theory that describes ensembles of particles. Meanwhile, however, experiments in many laboratories around the world (and even by Google, IBM, Microsoft and Intel) have demonstrated quantum control over single particles. This has led to the dream of a “second quantum revolution”, in which the strangeness and the power of quantum physics is harnessed to facilitate novel technologies that provide possibilities beyond those offered by any classical device. In diverse settings, theory and proof-of-concept experiments have shown that one can gain unique advantage by storing, transmitting, and processing information encoded in systems that exhibit quantum properties. Examples include quantum cryptography (that allows for unbreakable encryption), quantum measurements (that can provide unprecedented resolution), quantum simulation (that can help to gain insight into complex quantum systems and materials), and quantum information processing (that can dramatically improve computational power for specific tasks).This module will cover the basic principles that lie at the heart of the mentioned quantum technologies: The quantum harmonic oscillator and quantum two-level systems (qubits), generation and control of single photons and other quantum light fields, entanglement, decoherence, quantum measurement, experimental techniques for qubit control, quantum error correction, atomic clocks, quantum sensing, quantum communication, and the various types of quantum hardware used in current experiments.
Links	E-Learning-Kurs (z. B. Moodle) TUMonline-Eintrag TUMonline-Anmeldeverfahren

ergänzende Hinweise

Quantum theory was originally formulated as a statistical theory that describes ensembles of particles. Meanwhile, however, experiments in many laboratories around the world (and even by Google, IBM, Microsoft and Intel) have demonstrated quantum control over single particles. This has led to the dream of a “second quantum revolution”, in which the strangeness and the power of quantum physics is harnessed to facilitate novel technologies that provide possibilities beyond those offered by any classical device. In diverse settings, theory and proof-of-concept experiments have shown that one can gain unique advantage by storing, transmitting, and processing information encoded in systems that exhibit quantum properties. Examples include quantum cryptography (that allows for unbreakable encryption), quantum measurements (that can provide unprecedented resolution), quantum simulation (that can help to gain insight into complex quantum systems and materials), and quantum information processing (that can dramatically improve computational power for specific tasks).This module will cover the basic principles that lie at the heart of the mentioned quantum technologies: The quantum harmonic oscillator and quantum two-level systems (qubits), generation and control of single photons and other quantum light fields, entanglement, decoherence, quantum measurement, experimental techniques for qubit control, quantum error correction, atomic clocks, quantum sensing, quantum communication, and the various types of quantum hardware used in current experiments.

Links

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

Gleiche Lehrveranstaltungen (z. B. in anderen Semestern)

Semester	Titel	Dozent(en)	Termine
WS 2022/3	Quantum Technology	Reiserer, A.	Mi, 10:00–12:00, PH II 127
WS 2021/2	Quantum Technology	Reiserer, A.	Mi, 10:00–12:00, PH II 127
WS 2019/20	Quantum Technology	Reiserer, A.	Mi, 10:00–12:00, PH II 127
SS 2018	Quantum Technology	Rempe, G. Mitwirkende: Reiserer, A.	Mi, 10:00–12:00, PH II 127

Diese Webseite wird nicht mehr aktualisiert.

Quantentechnologie
Quantum Technology

Lehrveranstaltung 0000000774 im WS 2023/4

Basisdaten

Zuordnung zu Modulen

weitere Informationen

Gleiche Lehrveranstaltungen (z. B. in anderen Semestern)

QuantentechnologieQuantum Technology

Lehrveranstaltung 0000000774 im WS 2023/4

Basisdaten

Zuordnung zu Modulen

weitere Informationen

Gleiche Lehrveranstaltungen (z. B. in anderen Semestern)

Quantentechnologie
Quantum Technology