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Quantum-metrology estimation of spacetime parameters of the Earth outperforming classical precision

Quantum-metrology estimation of spacetime parameters of the Earth outperforming classical precision
Quantum-metrology estimation of spacetime parameters of the Earth outperforming classical precision
We consider quantum communication schemes where quantum optical signals are exchanged between a source on Earth and a satellite. The background curved spacetime affects the quantum state of the propagating photons. We employ quantum-metrology techniques to obtain optimal bounds for the precision of quantum measurements of relevant physical parameters encoded in the final state. We focus on satellites in low Earth orbits and we find that our scheme improves the precision of the measurement of the Schwarzschild radius obtained within previous studies. Therefore, our techniques can provide the theoretical tools for novel developments that can potentially outperform the state-of-the-art obtained through classical means. We also review the impact of the relativistic effects on a simple quantum key distribution protocol within satellite schemes and find that such effects can be greatly damaging if they are not properly accounted for.
2469-9926
Kohlrus, Jan
2ada319b-0cfa-4792-8c8d-294cffd645ac
Bruschi, David Edward
6b839b6e-2a84-428a-bb60-0a76397228df
Fuentes, Ivette
c6d65a4c-feac-44c1-9097-e0f6a9e0cf44
Kohlrus, Jan
2ada319b-0cfa-4792-8c8d-294cffd645ac
Bruschi, David Edward
6b839b6e-2a84-428a-bb60-0a76397228df
Fuentes, Ivette
c6d65a4c-feac-44c1-9097-e0f6a9e0cf44

Kohlrus, Jan, Bruschi, David Edward and Fuentes, Ivette (2019) Quantum-metrology estimation of spacetime parameters of the Earth outperforming classical precision. Physical Review A, 99 (3), [032350]. (doi:10.1103/PhysRevA.99.032350).

Record type: Article

Abstract

We consider quantum communication schemes where quantum optical signals are exchanged between a source on Earth and a satellite. The background curved spacetime affects the quantum state of the propagating photons. We employ quantum-metrology techniques to obtain optimal bounds for the precision of quantum measurements of relevant physical parameters encoded in the final state. We focus on satellites in low Earth orbits and we find that our scheme improves the precision of the measurement of the Schwarzschild radius obtained within previous studies. Therefore, our techniques can provide the theoretical tools for novel developments that can potentially outperform the state-of-the-art obtained through classical means. We also review the impact of the relativistic effects on a simple quantum key distribution protocol within satellite schemes and find that such effects can be greatly damaging if they are not properly accounted for.

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Published date: 29 March 2019

Identifiers

Local EPrints ID: 500682
URI: http://eprints.soton.ac.uk/id/eprint/500682
DOI: doi:10.1103/PhysRevA.99.032350
ISSN: 2469-9926
PURE UUID: 1b0780d9-86da-4956-a255-eb7f22f8598c

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Date deposited: 09 May 2025 16:44
Last modified: 09 May 2025 16:44

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Contributors

Author: Jan Kohlrus
Author: David Edward Bruschi
Author: Ivette Fuentes

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