Improving quantum state transfer: correcting non-Markovian and distortion effects

Peñas, Guillermo F; Puebla, Ricardo; José García-Ripoll, Juan

doi:10.1088/2058-9565/acf60a

Quantum Sci. Technol.

2023

DOI: 10.1088/2058-9565/acf60a

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Improving quantum state transfer: correcting non-Markovian and distortion effects

Guillermo F Peñas,

Ricardo Puebla,

Juan José García-Ripoll

Abstract: Quantum state transfer is a key operation for quantum information processing. The original pitch-and-catch protocols rely on flying qubits or single photons with engineered wavepacket shapes to achieve a deterministic, fast and high-fidelity transfer. Yet, these protocols overlook two important factors, namely, the distortion of the wavepacket during the propagation and non-Markovian effects during the emission and reabsorption processes due to time-dependent controls. Here we address both difficulties in a ge… Show more

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2024

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Success probabilities in time-reversal-based hybrid quantum state transfer

Randles,

van Enk

2024

Phys. Rev. A

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Success probabilities in time-reversal-based hybrid quantum state transfer

Randles,

van Enk

2024

Phys. Rev. A

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Multiplexed quantum state transfer in waveguides

Peñas,

Puebla,

García-Ripoll

2024

Phys. Rev. Research

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In this article, we consider a realistic waveguide implementation of a quantum network that serves as a testbed to show how to maximize the storage and manipulation of quantum information in QED setups. We analyze two approaches using wavepacket engineering and quantum state transfer protocols. First, we propose and design a family of orthogonal photons in the time domain. These photons allow for a selective interaction with distinct targeted qubits. Yet, mode multiplexing employing resonant nodes is largely spoiled by cross-talk effects. This motivates the second approach, namely, frequency multiplexing. Here we explore the limits of frequency multiplexing through the waveguide, analyzing its capabilities to host and faithfully transmit photons of different frequencies within a given bandwidth. We perform detailed one- and two-photon simulations and provide theoretical bounds for the fidelity of coherent quantum state transfer protocols under realistic conditions. Our results show that state-of-the-art experiments can employ dozens of multiplexed photons with global fidelities fulfilling the requirements imposed by fault-tolerant quantum computing. This is with the caveat that the conditions for single-photon fidelity are met. Published by the American Physical Society 2024

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Improving quantum state transfer: correcting non-Markovian and distortion effects

Cited by 2 publications

References 50 publications

Success probabilities in time-reversal-based hybrid quantum state transfer

Success probabilities in time-reversal-based hybrid quantum state transfer

Multiplexed quantum state transfer in waveguides

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