Diamond quantum networks for distributed quantum computation: Difference between revisions
Created page with "*Speaker: Taminiau, Tim *Affiliation: QuTech & Kavli Institute of Nanoscience, Delft University of Technology Quantum networks provide a promising way to realize quantum com..." |
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Quantum networks provide a promising way to realize quantum computations and simulations. Such networks consist of nodes that contain multiple qubits to store and process quantum states, and that are connected together by distributing entangled states through optical links using photons. Crucially, imperfections and errors can be overcome by distributing logical qubits, computations and error correction over the network [1]. This approach is naturally scalable to large sizes by connecting many independent modules, thus avoiding the challenges of a single large structure of ever increasing complexity. | Quantum networks provide a promising way to realize quantum computations and simulations. Such networks consist of nodes that contain multiple qubits to store and process quantum states, and that are connected together by distributing entangled states through optical links using photons. Crucially, imperfections and errors can be overcome by distributing logical qubits, computations and error correction over the network [1]. This approach is naturally scalable to large sizes by connecting many independent modules, thus avoiding the challenges of a single large structure of ever-increasing complexity. | ||
The nitrogen vacancy (NV) center in diamond is a promising candidate to realize such quantum networks, as it combines optical entanglement links [2] with long-lived multi-qubit nodes that can store and process quantum information [3-5]. In this talk I will discuss the recent progress of my group towards quantum networks for distributed quantum computations. | The nitrogen-vacancy (NV) center in diamond is a promising candidate to realize such quantum networks, as it combines optical entanglement links [2] with long-lived multi-qubit nodes that can store and process quantum information [3-5]. In this talk, I will discuss the recent progress of my group towards quantum networks for distributed quantum computations. | ||
[1] N. H. Nickerson, Y. Li, S. C. Benjamin, Nature Commun. 4, 1756 (2013) | [1] N. H. Nickerson, Y. Li, S. C. Benjamin, Nature Commun. 4, 1756 (2013) | ||
[2] B. Hensen et al., Nature 526, 682 (2015) | [2] B. Hensen et al., Nature 526, 682 (2015) | ||
[3] J. Cramer et al., Nature Commun. 7:11526 (2016) | [3] J. Cramer et al., Nature Commun. 7:11526 (2016) | ||
[4] M. H. Abobeih et al., Nature Commun. 9: 2552 (2018) | [4] M. H. Abobeih et al., Nature Commun. 9: 2552 (2018) | ||
[[Category:Qubits2019]] | [[Category:Qubits2019]] |
Latest revision as of 10:33, 26 March 2019
- Speaker: Taminiau, Tim
- Affiliation: QuTech & Kavli Institute of Nanoscience, Delft University of Technology
Quantum networks provide a promising way to realize quantum computations and simulations. Such networks consist of nodes that contain multiple qubits to store and process quantum states, and that are connected together by distributing entangled states through optical links using photons. Crucially, imperfections and errors can be overcome by distributing logical qubits, computations and error correction over the network [1]. This approach is naturally scalable to large sizes by connecting many independent modules, thus avoiding the challenges of a single large structure of ever-increasing complexity.
The nitrogen-vacancy (NV) center in diamond is a promising candidate to realize such quantum networks, as it combines optical entanglement links [2] with long-lived multi-qubit nodes that can store and process quantum information [3-5]. In this talk, I will discuss the recent progress of my group towards quantum networks for distributed quantum computations.
[1] N. H. Nickerson, Y. Li, S. C. Benjamin, Nature Commun. 4, 1756 (2013)
[2] B. Hensen et al., Nature 526, 682 (2015)
[3] J. Cramer et al., Nature Commun. 7:11526 (2016)
[4] M. H. Abobeih et al., Nature Commun. 9: 2552 (2018)