Detecting Primordial Gravitational Waves Signal from BICEP2 and Planck HFI 353GHz Dust Polarization

Abstract

The dust polarization is parameterized as a power law form of the multipole l: DXXl=AXXl(l+1)lαXX/(2π) (XX denotes BB or EE), where AXX is its amplitude with the ratio ABB/AEE=0.52 0.02 and αBB,EE=-2.42 0.02. Extrapolating to 150GHz from 353GHz yields a value of DBBl=80=(1.32 0.29)× 10-2μ K2 (and an additional uncertainty (+0.28,-0.24)× 10-2μ K2) over the range 40<l<120. Based on these data, we report the tensor-to-scalar ratio r=At/As defined at k0=0.05 Mpc -1 by joining the BICEP2+ Planck2013+WMAP9+BAO+HST and Planck HFI 353GHz dust polarization and its implication to the detection of the primordial gravitational waves. Considering the +r model, we found r<0.108 at 95\% confidence level with σstat=0.29 and r<0.129 at 95\% confidence level with σstat+extr=0.29+0.28. The results imply no significant evidence for the primordial gravitational waves in 1σ regions. However the post probability distribution of r peaks at a small positive value. And r moves to larger positive values when the extrapolation error bars are included. This might imply a very weak signal of the primordial gravitational waves. It also implies the crucial fact in calibrating the amplitude of the dust polarizations in detecting the primordial gravitational waves in the future. When the running of the scalar spectral tilt is included, we found r<0.079 at 95\% confidence level with σstat=0.29 and r=0.091-0.069+0.042 at 95\% confidence level with σstat+extr=0.29+0.28. The later one implies the detection of the primordial gravitational waves in 1σ regions at the cost of decreasing the value of DBBl=80 to 0.67-0.25+0.25.