Holographic dark information energy: predicted dark energy measurement

Gough, Paul (2013) Holographic dark information energy: predicted dark energy measurement. Entropy, 15 (3). pp. 1135-1151. ISSN 1099-4300

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Abstract

Several models have been proposed to explain the dark energy that is causing universe expansion to accelerate. Here the acceleration predicted by the Holographic Dark
Information Energy (HDIE) model is compared to the acceleration that would be produced by a cosmological constant. While identical to a cosmological constant at low redshifts, z < 1, the HDIE model results in smaller Hubble parameter values at higher redshifts, z > 1, reaching a maximum difference of 2.6 ± 0.5% around z ~ 1.7. The next generation of dark energy measurements, both those scheduled to be made in space (ESA’s Euclid and NASA’s WFIRST missions) and those to be made on the ground (BigBOSS, LSST and Dark Energy Survey), should be capable of determining whether such a difference exists or
not. In addition a computer simulation thought experiment is used to show that the algorithmic entropy of the universe always increases because the extra states produced by the accelerating expansion compensate for the loss of entropy from star formation.

Item Type: Article
Keywords: Landauer’s principle; Holographic principle; dark energy experiments; dark energy theory; cosmological constant experiments
Schools and Departments: School of Engineering and Informatics > Informatics
Subjects: Q Science > QB Astronomy > QB0980 Cosmogony. Cosmology
Related URLs:
Depositing User: Paul Gough
Date Deposited: 03 Apr 2013 09:30
Last Modified: 07 Mar 2017 05:09
URI: http://sro.sussex.ac.uk/id/eprint/44131

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