Reionization by active sources and its effects on the cosmic microwave background

Abstract

We investigate the possible effects of reionization by active sources on the cosmic microwave background. We concentrate on the sources themselves as the origin of reionization, rather than early object formation, introducing an extra period of heating motivated by the active character of the perturbations. Using reasonable parameters, this leads to four possibilities, depending on the time and duration of the energy input: delayed last scattering, double last scattering, shifted last scattering, and total reionization. We show that these possibilities are only very weakly constrained by the limits on spectral distortions from the Cosmic Background Explorer Far Infrared Absolute Spectrometer measurements. We illustrate the effects of these reionization possibilities on the angular power spectrum of temperature anisotropies and polarization for simple passive isocurvature models and simple coherent sources, observing the difference between passive and active models. Finally, we comment on the implications of this work for more realistic active sources, such as causal white noise and topological defect models. We show for these models that non-standard ionization histories can shift the peak in the cosmic microwave background power to larger angular scales.