http://arxiv.org/abs/1811.04083
Early dark energy (EDE) that behaves like a cosmological constant at early times (redshifts $z\gtrsim3000$) and then decays away like radiation or faster at later times can solve the Hubble tension. In these models, the sound horizon at decoupling is reduced resulting in a larger value of the Hubble parameter $H_0$ inferred from the cosmic microwave background (CMB). We consider two physical models for this EDE, one involving an oscillating scalar field and another a slowly-rolling field. We perform a detailed calculation of the evolution of perturbations in these models. A Markov Chain Monte Carlo search of the parameter space for the EDE parameters, in conjunction with the standard cosmological parameters, identifies regions in which $H_0$ inferred from Planck CMB data agrees with the SH0ES local measurement. In these cosmologies, current baryon acoustic oscillation and supernova data are described as successfully as in $\Lambda$CDM while the fit to Planck data is slightly improved. Future CMB and large-scale-structure surveys will further probe this scenario.
V. Poulin, T. Smith, T. Karwal, et. al.
Tue, 13 Nov 18
4/74
Comments: 4p+appendix, 3 figures. Comments welcome!
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