Constraining interacting dark energy with CMB and BAO future surveys
Jul 21, 2017
15 pages
Published in:
- Phys.Rev.D 96 (2017) 10, 103529
- Published: Nov 20, 2017
e-Print:
- 1707.06827 [astro-ph.CO]
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Abstract: (APS)
In this paper, we perform a forecast analysis to test the capacity of future baryon acoustic oscillation (BAO) and cosmic microwave background (CMB) experiments to constrain phenomenological interacting dark energy models using the Fisher matrix formalism. We consider a Euclid-like experiment, in which BAO measurements are one of the main goals, to constrain the cosmological parameters of alternative cosmological models. Moreover, additional experimental probes can more efficiently provide information on the parameters forecast, justifying also the inclusion in the analysis of a future ground-based CMB experiment mainly designed to measure the polarization signal with high precision. In the interacting dark energy scenario, a coupling between dark matter and dark energy modifies the conservation equations such that the fluid equations for both constituents are conserved as the total energy density of the dark sector. In this context, we consider three phenomenological models that have been deeply investigated in literature over the past years. We find that the combination of both CMB and BAO information can break degeneracies among the dark sector parameters for all three models, although to different extents. We find powerful constraints on, for example, the coupling constant when comparing it with present limits for two of the models, and their future statistical 3σ bounds could potentially exclude the null interaction for the combination of probes that is considered. However, for one of the models, the constraint on the coupling parameter does not improve the present result (achieved using a large combination of surveys), and a larger combination of probes appears to be necessary to eventually claim whether or not interaction is favored in that context.Note:
- 15 pages, 10 figures. Replaced to match published version
- dark energy: interaction
- oscillation: acoustic
- energy: density
- cosmic background radiation: polarization
- conservation law
- cosmological model
- coupling constant
- dark matter: parametrization
- statistical
- baryon
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