The clustering of galaxies in the SDSS-III Baryon Oscillation Spectroscopic Survey: constraints on the time variation of fundamental constants from the large-scale two-point correlation function

Abstract

We obtain constraints on the variation of the fundamental constants from the full shape of the redshift-space correlation function of a sample of luminous galaxies drawn from the Data Release 9 of the Baryonic Oscillations Spectroscopic Survey. We combine this information with data from recent CMB, BAO and H0 measurements. We focus on possible variations of the fine structure constant α and the electron mass me in the early universe, and study the degeneracies between these constants and other cosmological parameters, such as the dark energy equation of state parameter wDE, the massive neutrinos fraction f, the effective number of relativistic species Neff, and the primordial helium abundance YHe. When only one of the fundamental constants is varied, our final bounds are α / α0 = 0.9957-0.0042+0.0041 and me /(me)0 = 1.006-0.013+0.014. For their joint variation, our results are α / α0 = 0.9901-0.0054+0.0055 and me /(me)0 = 1.028 +/- 0.019. Although when me is allowed to vary our constraints on wDE are consistent with a cosmological constant, when α is treated as a free parameter we find wDE = -1.20 +/- 0.13; more than 1 σ away from its standard value. When f and α are allowed to vary simultaneously, we find f < 0.043 (95% CL), implying a limit of Σ m < 0.46 eV (95% CL), while for me variation, we obtain fnu < 0.086 (95% CL), which implies Σ m < 1.1 eV (95% CL). When Neff or YHe are considered as free parameters, their simultaneous variation with α provides constraints close to their standard values (when the H0 prior is not included in the analysis), while when me is allowed to vary, their preferred values are significantly higher. In all cases, our results are consistent with no variations of α or me at the 1 or 2 σ level.