Log-Poisson Non-Gaussianity of Lyα Transmitted Flux Fluctuations at High Redshift

Abstract

We investigate the non-Gaussian features of the IGM at redshift z 5 - 6 using Lyα transmitted flux of quasar absorption spectra and cosmological hydrodynamic simulation of the concordance universe. We show that the neutral hydrogen mass density field and Lyα transmitted flux fluctuations possess all the non-Gaussian features predicted by the log-Poisson hierarchy, which depends only on two dimensionless parameters β and γ, describing, respectively, the intermittence and singularity of the random fields. We find that the non-Gaussianity of the Lyα transmitted flux of quasars from z=4.9 to z=6.3 can be well reconstructed by the hydrodynamical simulation samples. Although the Gunn-Peterson optical depth and its variance underwent a significant evolution in the redshift range of 5 - 6, the intermittency measured by β is almost redshift-independent in this range. More interesting, the intermittency of quasar's absorption spectra on physical scales 0.1-1 h-1Mpc in redshift 5 - 6 are found to be about the same as that on physical scales 1-10 h-1Mpc at redshifts 2 - 4. Considering the Jeans length is less than 0.1 h-1Mpc at z 5, and 1 h-1Mpc at z 2, these results imply that the nonlinear evolution in high and low redshifts will lead the cosmic baryon fluid to a state similar to fully developed turbulence. The log-Poisson high order behavior of current high redshift data of quasar's spectrum can be explained by uniform UV background in the redshift range considered. We also studied the log-Poisson non-Gaussianity by considering inhomogeneous background. With several simplified models of inhomogeneous background, we found the effect of the inhomogeneous background on the log-Poisson non-Gaussianity is not larger than 1-sigma.