Warm Dark Matter meets Cold Dark Matter Isocurvature

Abstract

Isocurvature fluctuations can be generated in various scenarios in the early Universe. In particular, some specific models predict those with a blue-tilted spectrum, which is consistent with the constraints from cosmic microwave background such as Planck, although isocurvature fluctuations with an almost scale-invariant spectrum are severely constrained. We argue that cold dark matter (CDM) isocurvature fluctuations with blue-tilted spectrum are not only consistent with current cosmological data, but also can loosen the bound on the masses of warm dark matter (WDM), which suppresses small-scale power. In pure thermal WDM models with the adiabatic initial condition, a combination of the data from Lyman-α, gravitational lensing, and Milky Way satellites gives a lower bound on the WDM mass as 6~ keV at 95\% C.L. while mixed WDM+CDM models loosen these bounds to m WDM1 keV for a warm-fraction f WDM0.14 and m WDM600 eV for f WDM0.08. On the other hand, as we demonstrate, WDM scenarios with a blue-tilted CDM isocurvature power spectrum, even with only 1\% CDM contribution (f WDM0.99), can allow WDM masses as low as 600 eV. We further assess the implications of this ``warm + cold-isocurvature'' extension for the small-scale structure by performing N-body simulations, particularly focusing on nonlinear matter power spectrum and halo mass function.