A Simulation of LY alpha Absorption Forests in Linear Approximation of Cold Dark Matter and Cold Plus Hot Dark Matter Models

Abstract

Our goal in this paper is to test some popular dark matter models by Ly-alpha forest in QSO spectra. Recent observations of the size and velocity of Ly-alpha forest clouds have indicated that the Ly-alpha absorption is probably not given by collapsed objects, but pre-collapsed regions in the baryonic density field. Therefore, a linear approximation description would be able to provide valuable information. We developed a technique to simulate Ly-alpha forest as the absorption of such pre-collapsed regions under linear approximation regime. The simulated Ly-alpha forests in models of the standard cold dark matter (SCDM), the cold plus hot dark matter (CHDM), and the low-density flat cold dark matter (LCDM) have been confronted with observational features, including 1) the number density of Ly-alpha lines and its dependencies on redshift and equivalent width; 2) the distribution of equivalent widths and its redshift dependence; 3) clustering; and 4) the Gunn-Peterson effect. The "standard" CHDM model, i.e. 60% cold and 30% hot dark matters and 10% baryons, is found to be difficult to pass the Ly-alpha forest test, probably because it produces structures too late and favors to form structures on large scales instead of small scale objects like Ly-alpha clouds. Within a reasonable range of J_nu, the UV background radiation at high redshift, and delta_th, the threshold of the onset of gravitational collapse of the baryonic matter, the LCDM model is consistent with observational data in all above-mentioned four aspects. The model of SCDM can also fit with observation, but it requires a smaller J_nu and a higher delta_th. This suggests that whether a significant part of the Ly-alpha forest lines is located in the halos of collapsed objects would be crucial to the success of SCDM.Comment: 23 pages plus 14 figures in the PostScript format, tar-ed, compressed and then uudecoded. All these PS files and the original .LaTeX paper can be ftped from ftp://universe.physics.arizona.edu/incoming The paper is accepted for publication in Ap