A Truncated Primordial Power Spectrum and its Impact on CMB Polarization

Abstract

We investigate the impact of a hypothesized delayed initiation of inflation, characterized by a cutoff kmin to the primordial power spectrum in the cosmic microwave background (CMB). This cutoff affects both the scalar and tensor spectra, which therefore impacts several measurements of the temperature and polarization distributions. We calculate the angular power spectrum and correlation function with and without kmin in the context of Planck-LCDM, and demonstrate that a non-zero kmin significantly improves the alignment between theory and the observations, including the temperature, E-mode polarization, TE cross-correlation, Q+U polarization and Q-U polarization. It creates an observable signature in both the angular power spectrum and correlation function for all cases. We thus also explore the B-mode polarization, for which current data are not yet precise enough to determine kmin, but whose impact should be detectable with high-precision measurements using future missions, such as LiteBIRD, if the tensor-to-scalar ratio, r, is not much smaller than its current upper limit. We find that the introduction of kmin not only addresses large-angle anomalies in the CMB but also provides a more consistent framework for understanding the early Universe's inflationary phase. These findings highlight the importance of future high-precision CMB observations in validating the existence and implications of kmin.