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1. Deterministic multi-mode gates on a scalable photonic quantum computing platform

Author

Larsen, Mikkel V., Guo, Xueshi, Breum, Casper R., Neergaard-Nielsen, Jonas S., and Andersen, Ulrik L.

Subjects
Quantum Physics, Physics - Optics
Abstract

Quantum computing can be realized with numerous different hardware platforms and computational protocols. A highly promising approach to foster scalability is to apply a photonic platform combined with a measurement-induced quantum information processing protocol where gate operations are realized through optical measurements on a multipartite entangled quantum state -- a so-called cluster state. Heretofore, a few quantum gates on non-universal or non-scalable cluster states have been, but a full set of gates for universal scalable quantum computing has not been realized. We propose and demonstrate the deterministic implementation of a multi-mode set of measurement-induced quantum gates in a large two-dimensional (2D) optical cluster state using phase-controlled continuous variable quadrature measurements. Each gate is simply programmed into the phases of the high-efficiency quadrature measurements which execute the transformations by teleportation through the cluster state. Using these programmable gates, we demonstrate a small quantum circuit consisting of 10 single-mode gates and 2 two-mode gates on a three-mode input state. On this platform, fault-tolerant universal quantum computing is possible if the cluster state entanglement is improved and a supply of Gottesman-Kitaev-Preskill qubits is available. Moreover, it operates at the telecom wavelength and is therefore network connectable without quantum transducers.

Published
2020
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2. Deterministic generation of a two-dimensional cluster state

Author

Larsen, Mikkel V., Guo, Xueshi, Breum, Casper R., Neergaard-Nielsen, Jonas S., and Andersen, Ulrik L.

Subjects
Quantum Physics, Physics - Optics
Abstract

Measurement-based quantum computation offers exponential computational speed-up via simple measurements on a large entangled cluster state. We propose and demonstrate a scalable scheme for the generation of photonic cluster states suitable for universal measurement-based quantum computation. We exploit temporal multiplexing of squeezed light modes, delay loops, and beam-splitter transformations to deterministically generate a cylindrical cluster state with a two-dimensional (2D) topological structure as required for universal quantum information processing. The generated state consists of more than 30000 entangled modes arranged in a cylindrical lattice with 24 modes on the circumference, defining the input register, and a length of 1250 modes, defining the computation depth. Our demonstrated source of 2D cluster states can be combined with quantum error correction to enable fault-tolerant quantum computation.

Published
2019
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3. Distributed quantum sensing in a continuous variable entangled network

Author

Guo, Xueshi, Breum, Casper R., Borregaard, Johannes, Izumi, Shuro, Larsen, Mikkel V., Gehring, Tobias, Christandl, Matthias, Neergaard-Nielsen, Jonas S., and Andersen, Ulrik L.

Subjects
Quantum Physics, Physics - Optics
Abstract

Networking plays a ubiquitous role in quantum technology. It is an integral part of quantum communication and has significant potential for upscaling quantum computer technologies that are otherwise not scalable. Recently, it was realized that sensing of multiple spatially distributed parameters may also benefit from an entangled quantum network. Here we experimentally demonstrate how sensing of an averaged phase shift among four distributed nodes benefits from an entangled quantum network. Using a four-mode entangled continuous variable (CV) state, we demonstrate deterministic quantum phase sensing with a precision beyond what is attainable with separable probes. The techniques behind this result can have direct applications in a number of primitives ranging from biological imaging to quantum networks of atomic clocks.

Published
2019
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4. Fiber coupled EPR-state generation using a single temporally multiplexed squeezed light source

Author

Larsen, Mikkel V., Guo, Xueshi, Breum, Casper R., Neergaard-Nielsen, Jonas S., and Andersen, Ulrik L.

Subjects
Quantum Physics
Abstract

A prerequisite for universal quantum computation and other large-scale quantum information processors is the careful preparation of quantum states in massive numbers or of massive dimension. For continuous variable approaches to quantum information processing (QIP), squeezed states are the natural quantum resources, but most demonstrations have been based on a limited number of squeezed states due to the experimental complexity in up-scaling. The number of physical resources can however be significantly reduced by employing the technique of temporal multiplexing. Here, we demonstrate an application to continuous variable QIP of temporal multiplexing in fiber: Using just a single source of squeezed states in combination with active optical switching and a 200 m fiber delay line, we generate fiber-coupled Einstein-Podolsky-Rosen entangled quantum states. Our demonstration is a critical enabler for the construction of an in-fiber, all-purpose quantum information processor based on a single or few squeezed state quantum resources.

Published
2018
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6. Deterministic multi-mode gates on a scalable photonic quantum computing platform

Author

Larsen, Mikkel V., Guo, Xueshi, Breum, Casper R., Neergaard-Nielsen, Jonas S., Andersen, Ulrik L., Larsen, Mikkel V., Guo, Xueshi, Breum, Casper R., Neergaard-Nielsen, Jonas S., and Andersen, Ulrik L.

Abstract

Quantum computing can be realized with numerous different hardware platforms and computational protocols. A highly promising, and potentially scalable, idea is to combine a photonic platform with measurement-induced quantum information processing. In this approach, gate operations can be implemented through optical measurements on a multipartite entangled quantum state—a so-called cluster state. Previously, a few quantum gates on non-universal or non-scalable cluster states have been performed, but a full set of gates for universal scalable quantum computing has not been realized. Here we propose and demonstrate the deterministic implementation of a multi-mode set of measurement-induced quantum gates in a large two-dimensional optical cluster state using phase-controlled continuous-variable quadrature measurements. Each gate is programmed into the phases of high-efficiency quadrature measurements, which execute the transformations by teleportation through the cluster state. We further execute a small quantum circuit consisting of 10 single-mode gates and 2 two-mode gates on a three-mode input state. Fault-tolerant universal quantum computing is possible with this platform if the cluster-state entanglement is improved and a supply of states with Gottesman–Kitaev–Preskill encoding is available.

Published
2021

7. Distributed quantum sensing in a continuous variable entangled network

Author

Guo, Xueshi, Breum, Casper R., Borregaard, Johannes, Izumi, Shuro, Larsen, Mikkel Vilsbøll, Gehring, Tobias, Christandl, Matthias, Neergaard-Nielsen, Jonas S., Andersen, Ulrik L., Guo, Xueshi, Breum, Casper R., Borregaard, Johannes, Izumi, Shuro, Larsen, Mikkel Vilsbøll, Gehring, Tobias, Christandl, Matthias, Neergaard-Nielsen, Jonas S., and Andersen, Ulrik L.

Abstract

Networking is integral to quantum communications1 and has significant potential for upscaling quantum computer technologies2. Recently, it was realized that the sensing performances of multiple spatially distributed parameters may also be enhanced through the use of an entangled quantum network3,4,5,6,7,8,9,10. Here, we experimentally demonstrate how sensing of an averaged phase shift among four distributed nodes benefits from an entangled quantum network. Using a four-mode entangled continuous-variable state, we demonstrate deterministic quantum phase sensing with a precision beyond what is attainable with separable probes. The techniques behind this result can have direct applications in a number of areas ranging from molecular tracking to quantum networks of atomic clocks.

Published
2020

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