Your search keyword '"Ainley, E. M."' showing total 8 results

1. Multipartite Entanglement for Multi-node Quantum Networks

Author

Ainley, E. M., Agrawal, A., Main, D., Drmota, P., Nadlinger, D. P., Nichol, B. C., Srinivas, R., and Araneda, G.

Subjects

Quantum Physics

Abstract

Scaling the number of entangled nodes in a quantum network is a challenge with significant implications for quantum computing, clock synchronisation, secure communications, and quantum sensing. In a quantum network, photons interact with matter qubits at different nodes, flexibly enabling the creation of remote entanglement between them. Multipartite entanglement among multiple nodes will be crucial for many proposed quantum network applications, including quantum computational tasks and quantum metrology. To date, experimental efforts have primarily focused on generating bipartite entanglement between nodes, which is widely regarded as the fundamental quantum resource for quantum networks. However, relying exclusively on bipartite entanglement to form more complex multipartite entanglement introduces several challenges. These include the need for ancillary qubits, extensive local entangling operations which increases the preparation latency, and increasingly stringent requirements on coherence times as the number of nodes grows. Here, we analyse various schemes that achieve multipartite entanglement between nodes in a single step, bypassing the need for multiple rounds of bipartite entanglement. We demonstrate that different schemes can produce distinct multipartite entangled states, with varying fidelity and generation rates. Additionally, we discuss the applicability of these schemes across different experimental platforms, highlighting their primary advantages and disadvantages.

Published

2024

2. Distributed Quantum Computing across an Optical Network Link

Author

Main, D., Drmota, P., Nadlinger, D. P., Ainley, E. M., Agrawal, A., Nichol, B. C., Srinivas, R., Araneda, G., and Lucas, D. M.

Subjects

Quantum Physics

Abstract

Distributed quantum computing (DQC) combines the computing power of multiple networked quantum processing modules, enabling the execution of large quantum circuits without compromising on performance and connectivity. Photonic networks are well-suited as a versatile and reconfigurable interconnect layer for DQC; remote entanglement shared between matter qubits across the network enables all-to-all logical connectivity via quantum gate teleportation (QGT). For a scalable DQC architecture, the QGT implementation must be deterministic and repeatable; until now, there has been no demonstration satisfying these requirements. We experimentally demonstrate the distribution of quantum computations between two photonically interconnected trapped-ion modules. The modules are separated by $\sim$ 2 m, and each contains dedicated network and circuit qubits. By using heralded remote entanglement between the network qubits, we deterministically teleport a controlled-Z gate between two circuit qubits in separate modules, achieving 86% fidelity. We then execute Grover's search algorithm - the first implementation of a distributed quantum algorithm comprising multiple non-local two-qubit gates - and measure a 71% success rate. Furthermore, we implement distributed iSWAP and SWAP circuits, compiled with 2 and 3 instances of QGT, respectively, demonstrating the ability to distribute arbitrary two-qubit operations. As photons can be interfaced with a variety of systems, this technique has applications extending beyond trapped-ion quantum computers, providing a viable pathway towards large-scale quantum computing for a range of physical platforms., Comment: 16 pages, 7 figures, 2 tables

Published

2024

3. Experimental Quantum Advantage in the Odd-Cycle Game

Author

Drmota, P., Main, D., Ainley, E. M., Agrawal, A., Araneda, G., Nadlinger, D. P., Nichol, B. C., Srinivas, R., Cabello, A., and Lucas, D. M.

Subjects

Quantum Physics

Abstract

We report the first experimental demonstration of the odd-cycle game. We entangle two ions separated by ~2 m and the players use them to win the odd-cycle game with a probability ~26 sigma above that allowed by the best classical strategy. The experiment implements the optimal quantum strategy, is free of loopholes, and achieves 97.8(3) % of the theoretical limit to the quantum winning probability. We perform the associated Bell test and measure a nonlocal content of 0.54(2) -- the largest value for physically separate devices, free of the detection loophole, ever observed.

Published

2024

4. Squeezing, trisqueezing, and quadsqueezing in a spin-oscillator system

Author

Băzăvan, O., Saner, S., Webb, D. J., Ainley, E. M., Drmota, P., Nadlinger, D. P., Araneda, G., Lucas, D. M., Ballance, C. J., and Srinivas, R.

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

Quantum harmonic oscillators model a wide variety of phenomena ranging from electromagnetic fields to vibrations of atoms in molecules. Their excitations can be represented by bosons such as photons, single particles of light, or phonons, the quanta of vibrational energy. Linear interactions that only create and annihilate single bosons can generate coherent states of light or motion. Introducing nth-order nonlinear interactions, that instead involve n bosons, leads to increasingly complex quantum behaviour. For example, second-order interactions enable squeezing, used to enhance the precision of measurements beyond classical limits, while higher-order interactions create non-Gaussian states essential for continuous-variable quantum computation. However, generating nonlinear interactions is challenging, typically requiring higher-order derivatives of the driving field or specialized hardware. Hybrid systems, where linear interactions couple an oscillator to an additional spin, offer a solution and are readily available across many platforms. Here, using the spin of a single trapped ion coupled to its motion, we employ two linear interactions to demonstrate up to fourth-order bosonic interactions; we focus on generalised squeezing interactions and demonstrate squeezing, trisqueezing, and quadsqueezing. We characterise these interactions, including their spin dependence, and reconstruct the Wigner function of the resulting states. We also discuss the scaling of the interaction strength, where we drive the quadsqueezing interaction more than 100 times faster than using conventional techniques. Our method presents no fundamental limit in the interaction order n and applies to any platform supporting spin-dependent linear interactions. Strong higher-order nonlinear interactions unlock the study of fundamental quantum optics, quantum simulation, and computation in a hitherto unexplored regime.

Published

2024

5. Verifiable blind quantum computing with trapped ions and single photons

Author

Drmota, P., Nadlinger, D. P., Main, D., Nichol, B. C., Ainley, E. M., Leichtle, D., Mantri, A., Kashefi, E., Srinivas, R., Araneda, G., Ballance, C. J., and Lucas, D. M.

Subjects

Quantum Physics

Abstract

We report the first hybrid matter-photon implementation of verifiable blind quantum computing. We use a trapped-ion quantum server and a client-side photonic detection system networked via a fibre-optic quantum link. The availability of memory qubits and deterministic entangling gates enables interactive protocols without post-selection - key requirements for any scalable blind server, which previous realisations could not provide. We quantify the privacy at <~0.03 leaked classical bits per qubit. This experiment demonstrates a path to fully verified quantum computing in the cloud.

Published

2023

6. Robust Quantum Memory in a Trapped-Ion Quantum Network Node

Author

Drmota, P., Main, D., Nadlinger, D. P., Nichol, B. C., Weber, M. A., Ainley, E. M., Agrawal, A., Srinivas, R., Araneda, G., Ballance, C. J., and Lucas, D. M.

Subjects

Quantum Physics

Abstract

We integrate a long-lived memory qubit into a mixed-species trapped-ion quantum network node. Ion-photon entanglement first generated with a network qubit in Sr-88 is transferred to Ca-43 with 0.977(7) fidelity, and mapped to a robust memory qubit. We then entangle the network qubit with a second photon, without affecting the memory qubit. We perform quantum state tomography to show that the fidelity of ion-photon entanglement decays ~70 times slower on the memory qubit. Dynamical decoupling further extends the storage duration; we measure an ion-photon entanglement fidelity of 0.81(4) after 10s.

Published

2022

7. Verifiable Blind Quantum Computing with Trapped Ions and Single Photons

Author

Drmota, P., primary, Nadlinger, D. P., additional, Main, D., additional, Nichol, B. C., additional, Ainley, E. M., additional, Leichtle, D., additional, Mantri, A., additional, Kashefi, E., additional, Srinivas, R., additional, Araneda, G., additional, Ballance, C. J., additional, and Lucas, D. M., additional

Published

2024

8. Robust Quantum Memory in a Trapped-Ion Quantum Network Node

Author

Drmota, P., primary, Main, D., additional, Nadlinger, D. P., additional, Nichol, B. C., additional, Weber, M. A., additional, Ainley, E. M., additional, Agrawal, A., additional, Srinivas, R., additional, Araneda, G., additional, Ballance, C. J., additional, and Lucas, D. M., additional

Published

2023