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Quantum Algorithms
Timelike information broadcasting in cosmology
arXiv
Authors: Ana Blasco, Luis J. Garay, Mercedes Martin-Benito, Eduardo Martin-Martinez
Year
2015
Paper ID
26673
Status
Preprint
Abstract Read
~2 min
Abstract Words
153
Citations
N/A
Abstract
We study the transmission of information and correlations through quantum fields in cosmological backgrounds. With this aim, we make use of quantum information tools to quantify the classical and quantum correlations induced by a quantum massless scalar field in two particle detectors, one located in the early universe (Alice's) and the other located at a later time (Bob's). In particular, we focus on two phenomena: a) the consequences on the transmission of information of the violations of the strong Huygens principle for quantum fields, and b) the analysis of the field vacuum correlations via correlation harvesting from Alice to Bob. We will study a standard cosmological model first and then assess whether these results also hold if we use other than the general relativistic dynamics. As a particular example, we will study the transmission of information through the Big Bounce, that replaces the Big Bang, in the effective dynamics of Loop Quantum Cosmology.
Why This Paper Matters
- It adds a 2015 reference point for readers tracking recent quantum research.
- We study the transmission of information and correlations through quantum fields in cosmological backgrounds.
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