Abstract
We introduce the task of random-receiver quantum communication, in which a sender transmits a quantum message to a receiver selected from a list of n spatially separated parties. At the moment of transmission, the choice of receiver is unknown to the sender. Later, it becomes known to the n parties, who coordinate their actions by exchanging classical messages. In normal conditions, random-receiver quantum communication requires a noiseless quantum communication channel between the sender and each of the n receivers. In contrast, we show that random-receiver quantum communication can take place through noisy, entanglement-breaking channels if the order of such channels is coherently controlled by a quantum bit that is accessible through measurements. While this phenomenon is achieved with a single control qubit, it cannot be mimicked by adding a noiseless qubit channel from the sender to any of the receivers, or more generally, from the sender to any subset of k<n parties.Received 19 November 2020Accepted 26 May 2021DOI:https://doi.org/10.1103/PRXQuantum.2.020350Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.Published by the American Physical SocietyPhysics Subject Headings (PhySH)Research AreasQuantum channelsQuantum communicationQuantum correlations in quantum informationQuantum information processingQuantum networksQuantum Information
Highlights
The point-to-point transmission of quantum messages from a sender to a receiver is the cornerstone of quantum communication
A side channel to receiver Bi can be used to “smuggle” information directly to receiver Bi, bypassing the noisy channels Ai and Bi. While this approach can trivially transfer information to a known receiver, we show that it cannot achieve random receiver quantum communication, unless the sender is provided with one side channel for every receiver, and each of these side channels permits the faithful transmission of one qubit
In this paper we have introduced a quantum communication protocol, called random-receiver quantum communication
Summary
The point-to-point transmission of quantum messages from a sender to a receiver is the cornerstone of quantum communication. Suppose that the two channels can act in two alternative orders, AiBi and BiAi, and that their order is coherently controlled by a qubit, called the order qubit, in the thought experiment known as the quantum SWITCH [15,17] In this scenario, illustrated, we show that perfect random-receiver communication is possible even if all the channels (Ai, Bi)ni=1 have zero capacity to transmit quantum information. This protocol requires 1 qubit of quantum communication from the sender to each receiver
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