Damped Lyman Alpha Systems vs. Cold + Hot Dark Matter

Abstract

Damped Lyα systems provide possibly the most significant evidence for early structure formation, and thus a stringent constraint on the Cold + Hot Dark Matter (CHDM) cosmology. Using the numbers of halos in N-body simulations to normalize Press-Schechter (PS) estimates of the number densities of protogalaxies as a function of redshift, we find that CHDM with c//b = 0.6/0.3/0.1 is compatible with the damped Lyα data only at z<2.5, but that it is probably incompatible with data at z>3. The predictions of CHDM are quite sensitive to the neutrino fraction. We find that c//b = 0.725/0.20/0.075 is compatible with the z>3 data. With one massive neutrino species, this corresponds to lowering the neutrino mass from 7.0 to 4.7 eV, for H0=50 and T=2.726 K. By analysing our numerical simulations with different resolutions and box sizes as well as those of Ma \& Bertchinger (1994), we show that for the CHDM models with =0.2--0.3 the PS approximation should be used with Gaussian filter with δc=1.3-1.4 if one tries to recover the total mass of a collapsed halo and to include nonlinear effects, due to waves both longer and shorter than those within the simulation box.

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