Course Exam
260075 VO Experiments in Quantum Optics and Quantum Information (2019W)
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Registration/Deregistration
Note: The time of your registration within the registration period has no effect on the allocation of places (no first come, first served).
- Registration is open from We 03.06.2020 08:00 to Mo 28.09.2020 12:00
- Deregistration possible until Mo 28.09.2020 12:00
Examiners
Information
Examination topics
All content of the lectures and exercises* Reminder: Advanced Atomic Physics and Atom Light Interaction
* Model Systems of Quantum Optics and Information: 2-level systems, quantum harmonic
oscillator, quantized light field
* Ultracold Matter I: Laser cooling, Trapping of atoms and ions
* Ultracold Matter II: Bose Einstein Condensates, Lattices, Model Systems of Condensed Matter Physics
* Massive superpositions I: Matter-waves: Foundations
* Massive superpositions II: Matter-wave assisted metrology (fundamental constants, inertial forces, biophysical chemistry)
* Internal state coherence I:Atomic Clocks: From Rabis Beam Machine to Lattice Clocks and
Quantum Logic Clocks
* Internal state coherence II:NV Center based quantum information processing and sensing:
single photons and B-sensors
* Nanomechanics /Nanoparticle Quantum Optics
* Elementary Quantum Info Systems I: Rydberg atoms in Cavities
* Elementary Quantum Info Systems II: Superconducting quantum circuits
* Elementary Quantum Info Systems III: Ion trap based quantum optics & information
processing
* Elementary Quantum Info Systems IV: Entangled atoms and NV centers
* Elementary Quantum Info Systems IV: NMR Quantum Computing with molecules
* Bell Experiments (all generations, steering, loophole free, etc)
* Quantum Teleportation, Quantum Swapping, GHZ, optical BSA
* Quantum Communication, QKD, RandomAccess Codes, One-Time-Programms, oblivous
transfer
* Quantum Repeaters, Atom-Light, DLCZ, all-optical
* Quantum Computing Concepts; Architectures, Physical Systems, Benchmarks
(Google/IBM/ions)
* Photonic Quantum Computing (KLM, HOM, 2-photon gates, Graphene-based gates)
* Photonic Quantum Computing (MBQC, Cluster States, BQC, Quantum Dots,
Flow,Repeaters)
* Quantum Machine Learning (Agents, experimental implementations, Neuromorphic
networks etc)
* Photonic Quantum Technology + Photon-Spin Systems (Quantum Dots, Spin Systems, etc)
* Quantum Simulation (Digital, Adiabatic, Trotter extension, atomic lattices, photons spin
frustration, ions gauge field)
* Quantum Metrology (N00N states, Burke states, squeezed states LIGO)
* Experiments at the interface of quantum and gravity
* Quantum CausalityWhile presence in the exercises is no formal requirement, the material of the exercises is part of the final test. Participation is highly recommended
* Model Systems of Quantum Optics and Information: 2-level systems, quantum harmonic
oscillator, quantized light field
* Ultracold Matter I: Laser cooling, Trapping of atoms and ions
* Ultracold Matter II: Bose Einstein Condensates, Lattices, Model Systems of Condensed Matter Physics
* Massive superpositions I: Matter-waves: Foundations
* Massive superpositions II: Matter-wave assisted metrology (fundamental constants, inertial forces, biophysical chemistry)
* Internal state coherence I:Atomic Clocks: From Rabis Beam Machine to Lattice Clocks and
Quantum Logic Clocks
* Internal state coherence II:NV Center based quantum information processing and sensing:
single photons and B-sensors
* Nanomechanics /Nanoparticle Quantum Optics
* Elementary Quantum Info Systems I: Rydberg atoms in Cavities
* Elementary Quantum Info Systems II: Superconducting quantum circuits
* Elementary Quantum Info Systems III: Ion trap based quantum optics & information
processing
* Elementary Quantum Info Systems IV: Entangled atoms and NV centers
* Elementary Quantum Info Systems IV: NMR Quantum Computing with molecules
* Bell Experiments (all generations, steering, loophole free, etc)
* Quantum Teleportation, Quantum Swapping, GHZ, optical BSA
* Quantum Communication, QKD, RandomAccess Codes, One-Time-Programms, oblivous
transfer
* Quantum Repeaters, Atom-Light, DLCZ, all-optical
* Quantum Computing Concepts; Architectures, Physical Systems, Benchmarks
(Google/IBM/ions)
* Photonic Quantum Computing (KLM, HOM, 2-photon gates, Graphene-based gates)
* Photonic Quantum Computing (MBQC, Cluster States, BQC, Quantum Dots,
Flow,Repeaters)
* Quantum Machine Learning (Agents, experimental implementations, Neuromorphic
networks etc)
* Photonic Quantum Technology + Photon-Spin Systems (Quantum Dots, Spin Systems, etc)
* Quantum Simulation (Digital, Adiabatic, Trotter extension, atomic lattices, photons spin
frustration, ions gauge field)
* Quantum Metrology (N00N states, Burke states, squeezed states LIGO)
* Experiments at the interface of quantum and gravity
* Quantum CausalityWhile presence in the exercises is no formal requirement, the material of the exercises is part of the final test. Participation is highly recommended
Assessment and permitted materials
Modul Test, 3 hours written exam. Only paper and pencil and non-programmable pocket computer allowed
Minimum requirements and assessment criteria
50% of all points during the final exam is the minimum requirement to pass. Grades above this threshold are linear.
Last modified: Fr 15.01.2021 00:21