2008A&A...491..465D

We investigated a set of high-resolution (R∼45000), high signal-to-noise (S/N∼70) quasar spectra to search for the signature of the so-called proximity effect in the HI Lyα forest. The sample consists of 40 bright quasars with redshifts in the range 2.1<z<4.7. Using the flux transmission statistic, we determined the redshift evolution of the HI effective optical depth in the Lyman forest between 2≲z≲4.5, finding good agreement with previous measurements based on smaller samples. We also see the previously reported dip in τ_eff(z) around redshift z∼3.3, but as the significance of that feature is only 2.6σ, we consider this detection tentative. Comparing the flux transmission near each quasar with what was expected from the overall trend of τ_eff(z), we clearly detect the proximity effect not only in the combined quasar sample, but also towards each individual line of sight at high significance, albeit with varying strength. We quantify this strength using a simple prescription based on a fiducial value for the intensity of the metagalactic UV background (UVB) radiation field at 1 Ryd, multiplied by a free parameter that varies from QSO to QSO. The observed proximity effect strength distribution (PESD) is asymmetric, with an extended tail towards values corresponding to a weak effect. We demonstrate that this is not simply an effect of gravitational clustering around quasars, as the same asymmetry is already present in the PESD predicted for purely Poissonian variance in the absorption lines. We present the results of running the same analysis on simulated quasar spectra generated by a simple Monte-Carlo code. Comparing the simulated PESD with observations, we argue that the standard method of determining the UVB intensity J_ν0 by averaging over several lines of sight is heavily biased towards high values of J_ν0 because of the PESD asymmetry. Using instead the mode of the PESD provides an estimate of J_ν0 that is unbiased with respect to his effect. For our sample we get a modal value for the UVB intensity of logJ_ν0=-21.51±0.15 (in units of erg/cm2/s/Hz/sr) for a median quasar redshift of 2.73. With J_ν0 fixed we then corrected τeff near each quasar for local ionisation and estimated the amount of excess HI absorption attributed to gravitational clustering. On scales of ∼3 Mpc, only a small minority of quasars show substantial overdensities of up to a factor of a few in τeff; these are exactly the objects with the weakest proximity effect signatures. After removing those quasars residing in overdense regions, we redetermined the UVB intensity using a hybrid approach of sample averaging and statistical correction for the PESD asymmetry bias, arriving at logJ_ν0=-21.46^+0.14_–0.21. This is the most accurate measurement of J_ν0 to date. We present a new diagnostic based on the shape and width of the PESD that strongly supports our conclusion that there is no systematic overdensity bias for the proximity effect. This additional diagnostic breaks the otherwise unavoidable degeneracy of the proximity effect between UVB and overdensity. We then applied our hybrid approach to estimate the redshift evolution of the UVB intensity and found tentative evidence of a mild decrease in logJ_ν0 with increasing redshift, by a factor of ∼0.4 from z=2 to z=4. Our results are in excellent agreement with earlier predictions for the evolving UVB intensity, and they also agree well with other methods of estimating the UVB intensity. In particular, our measured UVB evolution is much slower than the change in quasar space densities between z=4 and z=2, supporting the notion of a substantial contribution of star-forming galaxies to the UVB at high redshift.