Abstract
Quantum repeaters are a promising platform for realizing long-distance quantum communication and thus could form the backbone of a secure quantum internet, a scalable quantum network, or a distributed quantum computer. Repeater protocols that encode information in single- or multi-photon states are limited by transmission losses and the cost of implementing entangling gates or Bell measurements. In this work, we consider implementing a quantum repeater protocol using Gottesman-Kitaev-Preskill (GKP) qubits. These qubits are natural elements for quantum repeater protocols, because they allow for deterministic Gaussian entangling operations and Bell measurements, which can be implemented at room temperature. The GKP encoding is also capable of correcting small displacement errors. At the cost of additional Gaussian noise, photon loss can be converted into a random displacement error channel by applying a phase-insensitive amplifier. Here we show that a similar conversion can be achieved in two-way repeater protocols by using phase-sensitive amplification applied in the post-processing of the measurement data, resulting in less overall Gaussian noise per (sufficiently short) repeater segment. We also investigate concatenating the GKP code with higher level qubit codes while leveraging analog syndrome data, post-selection, and path-selection techniques to boost the rate of communication. We compute the secure key rates and find that GKP repeaters can achieve a comparative performance relative to methods based on photonic qubits while using orders-of-magnitude fewer qubits.
Highlights
Reliable quantum communication protocols are an essential ingredient for creating a secure quantum internet [1,2], implementing secure classical communication [3,4,5,6,7] and distributed quantum cryptographic protocols [8,9]
We show that photon loss can be converted to Gaussian displacement noise via phase-sensitive amplifiers, circumventing the additional noise added by the aforementioned method that relies on phase-insensitive amplification
We calculate the secure-key rates for all three amplification techniques, and show the merit of using the highly reliable measurement (HRM) to improve the secure-key rate at the expense of the success probability of quantum communication
Summary
Reliable quantum communication protocols are an essential ingredient for creating a secure quantum internet [1,2], implementing secure classical communication [3,4,5,6,7] and distributed quantum cryptographic protocols [8,9]. By suppressing the effect of photon loss in the transmission channels through suitable quantum error correction codes and directly sending encoded logical qubits, the necessity of two-way classical communication (as required in memory-based repeaters to inform each station on successful entanglement distributions and manipulations of other stations) can be entirely circumvented. As a consequence, such so-called third-generation quantum repeaters [17] are limited only by the elementary time units needed for locally preparing, processing, and detecting quantum states at each station, independent of distance-dependent waiting times for classical signals.
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