Non-thermal neutrino-like hot dark matter in light of the S8 tension

Abstract

The prediction of S8σ8(m/0.3)0.5 -- where σ8 is the root mean square of matter fluctuations on a 8 h-1Mpc scale -- once calibrated on Planck CMB data is 2-3σ lower than its direct estimate by a number of weak lensing surveys. In this paper, we explore the possibility that the 'S8-tension' is due to a non-thermal hot dark matter (HDM) fractional contribution to the universe energy density leading to a power suppression at small-scales in the matter power spectrum. Any HDM models can be characterized by its effective mass msp eff and its contribution to the relativistic degrees of freedom at CMB decoupling N eff. Taking the specific example of a sterile particle produced from the decay of the inflaton during a matter dominated era, we find that from Planck only the tension can be reduced below 2σ, but Planck does not favor a non-zero msp eff, N eff. In combination with a measurement of S8 from KIDS1000+BOSS+2dfLenS, the S8-tension would hint at the existence of a particle of mass msp eff 0.67-0.48+0.26 eV with a contribution to N eff 0.060.05. However, Pantheon and BOSS BAO/fσ8 data restricts the particle mass to msp eff 0.48-0.36+0.17 and contribution to N eff 0.046-0.031+0.004. We discuss implications of our results for other canonical non-thermal HDM models -- the Dodelson-Widrow model and a thermal sterile particle with a different temperature in the hidden sector. We report competitive results on such hidden sector temperature which might have interesting implications for particle physics model building, in particular connecting the S8-tension to the longstanding short baseline oscillation anomaly.