Constraining the ratio of median pixel optical depth profile around z ~ 4 quasars using the longitudinal proximity effect

TL;DR

This study analyzes the longitudinal proximity effect around high-redshift quasars to constrain the ratio of median pixel optical depths, revealing a significant excess close to quasars and its dependence on quasar luminosity.

Contribution

It provides the first detailed measurement of the optical depth ratio profile around z~4 quasars using high-quality spectra and models the radial dependence with an exponential profile.

Findings

Significant proximity effect detected up to 12 Mpc from quasars.

Optical depth ratio peaks within 6 Mpc, indicating excess ionization.

The optical depth ratio profile depends on quasar luminosity.

Abstract

We present a detailed study of the longitudinal proximity effect using a sample of 85 quasars spanning an emission redshift range of $3.5 \leq z_{em} \leq 4.5$ and Lyman continuum luminosity ($L_{912}$) ranging from 1.06$\times 10^{31}$ to 2.24$\times 10^{32}$ erg s$^{-1}$ Hz$^{-1}$. We use the high-quality spectra of these quasars obtained at a spectral resolution of $R\sim$ 5100 and S/N $\sim$ 30 using X-SHOOTER spectrograph mounted on the Very Large Telescope (VLT). In our analysis, we compared the transmitted flux and pixel optical depth of the Ly$\alpha$ absorption originating from the vicinity of quasars to those from the general intergalactic medium by using a redshift matched control sample. The longitudinal proximity effect is found up to $r \leq 12$ Mpc (proper) from quasars. By appropriately scaling up the pixel optical depth in the vicinity of quasars to account for the excess ionization by quasars, we constrain the ratio of median HI optical depth in the vicinity of the quasar to that of the IGM ($R_\tau(r)$). The $R_\tau (r)$ is found to be significantly higher than unity up to 6 Mpc from the quasar with a typical radial profile of the form $R_\tau(r) = 1+A \times exp(-r/r_0)$ with $A=9.16\pm 0.68$ and $r_0= 1.27\pm 0.08$ Mpc. The integrated value of the scaled pixel optical depth over the radial bin of 0-6 Mpc is found to be higher by a factor of $2.55 \pm 0.17$ than the corresponding integrated value of the median pixel optical depth of the IGM. We also found $R_\tau (r)$ to be luminosity dependent.