Towards Solid-State Quantum Repeaters: Ultrafast, Coherent Optical Control and Spin-Photon Entanglement in Charged InAs Quantum Dots summarizes several state-of-the-art coherent spin manipulation experiments in III-V quantum dots. Both high-fidelity optical manipulation, decoherence due to nuclear spins and the spin coherence extraction are discussed, as is the generation of entanglement between a single spin qubit and a photonic qubit. The experimental results are analyzed and discussed in the context of future quantum technologies, such as quantum repeaters.
Single spins in optically active semiconductor host materials have emerged as leading candidates for quantum information processing (QIP). The quantum nature of the spin allows for encoding of stationary, memory quantum bits (qubits), and the relatively weak interaction with the host material preserves the spin coherence. On the other hand, optically active host materials permit direct interfacing with light, which can be used for all-optical qubit manipulation, and for efficiently mapping matter qubits into photonic qubits that are suited for long-distance quantum communication.
| ISBN: | 9783319374963 |
| Publication date: | 23rd August 2016 |
| Author: | Kristiaan De Greve |
| Publisher: | Springer an imprint of Springer International Publishing |
| Format: | Paperback |
| Pagination: | 148 pages |
| Series: | Springer Theses |
| Genres: |
Materials science Condensed matter physics (liquid state and solid state physics) Particle and high-energy physics Quantum physics (quantum mechanics and quantum field theory) Mathematical theory of computation |
Towards Solid-State Quantum Repeaters: Ultrafast, Coherent Optical Control and Spin-Photon Entanglement in Charged InAs Quantum Dots summarizes several state-of-the-art coherent spin manipulation experiments in III-V quantum dots. Both high-fidelity optical manipulation, decoherence due to nuclear spins and the spin coherence extraction are discussed, as is the generation of entanglement between a single spin qubit and a photonic qubit. The experimental results are analyzed and discussed in the context of future quantum technologies, such as quantum repeaters.
Single spins in optically active semiconductor host materials have emerged as leading candidates for quantum information processing (QIP). The quantum nature of the spin allows for encoding of stationary, memory quantum bits (qubits), and the relatively weak interaction with the host material preserves the spin coherence. On the other hand, optically active host materials permit direct interfacing with light, which can be used for all-optical qubit manipulation, and for efficiently mapping matter qubits into photonic qubits that are suited for long-distance quantum communication.
Towards Solid-State Quantum Repeaters features in the following genres: Materials science, Condensed matter physics (liquid state and solid state physics), Particle and high-energy physics, Quantum physics (quantum mechanics and quantum field theory), Mathematical theory of computation
Towards Solid-State Quantum Repeaters is available in Paperback, Hardback
Towards Solid-State Quantum Repeaters was written by Kristiaan De Greve and published by Springer an imprint of Springer International Publishing
Towards Solid-State Quantum Repeaters has 148 pages
Yes it is part of Springer Theses series