The impact of theoretical assumptions in the determination of the neutrino effective number from future CMB measurements

Abstract

One of the major goals of future Cosmic Microwave Background measurements is the accurate determination of the effective number of neutrinos N eff. Reaching an experimental sensitivity of N eff = 0.013 could indeed falsify the presence of any non-standard relativistic particles at 95 \% c.l.. In this paper, we test how this future constraint can be affected by the removal of two common assumptions: a negligible running of the inflationary spectral index n run and a precise determination of the neutron lifetime τn. We first show that the constraints on N eff could be significantly biased by the unaccounted presence of a running of the spectral index. Considering the Stage-IV experiment, a negative running of dn/ d k= - 0.002 could mimic a positive variation of N eff = 0.03. Moreover, given the current discrepancies between experimental measurements of the neutron lifetime τn, we show that the assumption of a conservative error of τn 10s could bring to a systematic error of N eff = 0.02. Complementary cosmological constraints on the running of the spectral index and a solution to the neutron lifetime discrepancy are therefore needed for an accurate and reliable future CMB bound of N eff at percent level.