Related papers: Hardware-Efficient Entanglement Distillation Using Bosonic Systems

Hardware-Efficient Entanglement Distillation Using Bosonic Systems

URL: http://arxiv.org/abs/2503.09700v1
Date: Wed, 12 Mar 2025 18:00:03 GMT
Title: Hardware-Efficient Entanglement Distillation Using Bosonic Systems
Authors: Shoham Jacoby, Rotem Arnon-Friedman, Serge Rosenblum,
Abstract summary: High-fidelity entanglement shared between quantum systems is an essential resource for quantum communication and computation.<n>We propose to leverage the high-dimensional Hilbert space of a single pair of bosonic systems to store a large amount of entanglement.<n>We show that our protocol significantly enhances the fidelity of the entangled state in the presence of naturally occurring loss and dephasing errors.
Score: 1.8570591025615457
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: High-fidelity entanglement shared between distant quantum systems is an essential resource for quantum communication and computation. Entanglement distillation addresses this need by converting multiple noisy Bell pairs into fewer higher-fidelity pairs, using only local quantum operations and classical communication. However, this approach typically requires a substantial overhead in the number of qubits. To bypass this hurdle, we propose to leverage the high-dimensional Hilbert space of a single pair of bosonic systems to store a large amount of entanglement, replacing the need for multi-qubit systems. To distill entanglement in such a setup, we devise a new entanglement distillation protocol, tailored for bosonic systems. The protocol converts a highly-entangled noisy state between two bosonic systems into a lower-dimensional but high-fidelity entangled state, using only local bosonic operations. We show that our protocol significantly enhances the fidelity of the entangled state in the presence of naturally occurring loss and dephasing errors. Compared to methods relying on multiple Bell pairs, our scheme offers a more hardware-efficient strategy, providing a practical route toward the realization of entanglement distillation.

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