Cosmological parameter fittings with the BICEP2 data

TL;DR

This paper combines Planck, WMAP, BAO, and BICEP2 data to constrain cosmological parameters in the ΛCDM model, especially focusing on primordial power spectra and tensor modes, using MCMC analysis.

Contribution

It provides new constraints on cosmological parameters by incorporating BICEP2 B-mode data without assuming the single-field slow roll inflation relation.

Findings

Slight preference for a blue tilt in tensor spectral index n_t

Measured tensor-to-scalar ratio r is slightly lower than BICEP's estimate

Most other parameters remain consistent with previous constraints

Abstract

Combining the latest Planck, Wilkinson Microwave Anisotropy Probe (WMAP), and baryon acoustic oscillation (BAO) data, we exploit the recent cosmic microwave background (CMB) B-mode power spectra data released by the BICEP2 collaboration to constrain the cosmological parameters of the $\Lambda$CDM model, esp. the primordial power spectra parameters of the scalar and the tensor modes, $n_s,\alpha_s, r, n_t$. We obtained constraints on the parameters for a lensed $\Lambda$CDM model using the Markov Chain Monte Carlo (MCMC) technique, the marginalized $68\%$ bounds are $r = 0.1043\pm_{0.0914}^{0.0307}$, $n_s = 0.9617\pm_{0.0061}^{ 0.0061}$, $\alpha_s = -0.0175\pm_{0.0097}^{0.0105}$, $n_t = 0.5198\pm_{0.4579}^{0.4515}$. We found that a blue tilt for $n_t$ is favored slightly, but it is still well consistent with flat or even red tilt. Our $r$ value is slightly smaller than the one obtained by the BICEP team, as we allow $n_t$ as a free parameter without imposing the single-field slow roll inflation consistency relation. If we impose this relation, $r=0.2130\pm_{0.0609}^{0.0446}$. For most other parameters, the best fit values and measurement errors are not altered much by the introduction of the BICEP2 data.