The virial mode kv approach to Structure Formation with Warm Dark Matter

Abstract

The small scale structure opens a window to constrain the dynamical properties of Dark Matter. Here we study the clustering of warm dark matter (WDM) in a semi-analytical approach and compared the linear power spectrum of WDM with cold dark matter (CDM) employing a new transfer function Tv(a,k) in terms of the viral wave number kv=2π/λv corresponding to a structure with a viral radius rv=λv/2, half the size of the free streaming scale radius rv=rfs/2=λfs/4. The virial mass Mv contained in this structure corresponds to the lightest structure formed for a WDM particle becoming non-relativistic at the scale factor anr with the corresponding λfs. The viral transfer function Tv(a,k)=[1+ (k/kv )βv ]γv is given in terms of the viral mode kv and two constant parameters βv and γv. We compare Tv(a,k) with the Boltzmann code CLASS for WDM in the mass range 1-10 keV and we obtain the constraint βvγv=-18 with =1.020 0.025. In the standard approach the transfer function is given by T(a,k)=[1+(α\, k )β]γ Viel:2005qj where α encodes the dynamical properties of WDM and must be numerically adjusted by means of a Boltzmann code. In contrast, in our viral approach the physical quantity kv is simply given in terms of the free streaming scale λfs and can be analytically determined. Our viral proposal has a good agreement with CLASS and improves slightly the results from the standard transfer function. To conclude, we have proposed a new physically motivated transfer function Tv(a,k) where the properties of WDM are encoded in the viral wave number kv, is straightforward to determine and improves the prediction of WDM clustering properties.