Related papers: Superadditivity of channel capacity through quantum fields

Superadditivity of channel capacity through quantum fields

URL: http://arxiv.org/abs/2002.04153v2
Date: Tue, 5 May 2020 10:33:48 GMT
Title: Superadditivity of channel capacity through quantum fields
Authors: Koji Yamaguchi, Aida Ahmadzadegan, Petar Simidzija, Achim Kempf and Eduardo Mart\'in-Mart\'inez
Abstract summary: We study the scenario where a sender, Alice, causes information-carrying disturbances in a quantum field. We find that the channel capacity between Alice and a receiver, Bob, is enhanced by Bob placing detectors not only inside but also outside the causal future of Alice's encoding operation.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Given that any communication is communication through quantum fields, we here study the scenario where a sender, Alice, causes information-carrying disturbances in a quantum field. We track the exact spread of these disturbances in space and time by using the technique of quantum information capsules (QIC). We find that the channel capacity between Alice and a receiver, Bob, is enhanced by Bob placing detectors not only inside but in addition also outside the causal future of Alice's encoding operation. Intuitively, this type of superadditivity arises because the field outside the causal future of Alice is entangled with the field inside Alice's causal future. Hence, the quantum noise picked up by Bob's detectors outside Alice's causal future is correlated with the noise of Bob's detectors inside Alice's causal future. In effect, this correlation allows Bob to improve the signal-to-noise ratio of those of his detectors which are in the causal future of Alice. Further, we develop the multimode generalization of the QIC technique. This allows us to extend the analysis to the case where Alice operates multiple localized and optionally entangled emitters. We apply the new techniques to the case where Alice enhances the channel capacity by operating multiple emitters that are suitably lined up and pre-timed to generate a quantum shockwave in the field.

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