Relativistic Motion Generates Quantum Gates and Entanglement Resonances

David Edward Bruschi; Andrzej Dragan; Antony R. Lee; Ivette Fuentes; and Jorma Louko

arXiv:1201.0663·quant-ph·June 10, 2016

Relativistic Motion Generates Quantum Gates and Entanglement Resonances

David Edward Bruschi, Andrzej Dragan, Antony R. Lee, Ivette Fuentes, and Jorma Louko

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TL;DR

This paper demonstrates that relativistic motion, specifically nonuniform acceleration, can be harnessed to generate quantum gates and entanglement resonances in continuous-variable quantum systems, revealing a novel method for quantum control.

Contribution

It introduces a new approach where relativistic motion induces quantum gates and entanglement resonances, expanding the toolkit for quantum information processing.

Findings

01

Relativistic motion can generate quantum gates in continuous-variable systems.

02

Periodic trajectories induce observable entanglement resonances.

03

Nonuniform acceleration leads to well-known two-mode quantum gates.

Abstract

We show that the relativistic motion of a quantum system can be used to generate quantum gates. The nonuniform acceleration of a cavity is used to generate well-known two-mode quantum gates in continuous variables. Observable amounts of entanglement between the cavity modes are produced through resonances which appear by repeating periodically any trajectory.

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