Mapping quasar light echoes in 3D with Ly{\alpha} forest tomography

TL;DR

This paper introduces a new 3D mapping method using Lyα forest tomography to detect and analyze quasar light echoes, revealing quasar radiative histories and emission geometries with feasible observational setups.

Contribution

The paper presents a novel Bayesian method and simulation-based analysis for detecting quasar light echoes in 3D using Lyα forest tomography, enabling detailed quasar age and emission geometry measurements.

Findings

Light echoes detectable for luminous quasars at z=3-5

Achieves <20% precision on quasar age estimates

Requires modest observational resources with existing instruments

Abstract

The intense radiation emitted by luminous quasars dramatically alters the ionization state of their surrounding IGM. This so-called proximity effect extends out to tens of Mpc, and manifests as large coherent regions of enhanced Lyman-$\alpha$ (Ly$\alpha$) forest transmission in absorption spectra of background sightlines. Here we present a novel method based on Ly$\alpha$ forest tomography, which is capable of mapping these quasar `light echoes' in three dimensions. Using a dense grid (10-100) of faint ($m_r\approx24.7\,\mathrm{mag}$) background galaxies as absorption probes, one can measure the ionization state of the IGM in the vicinity of a foreground quasar, yielding detailed information about the quasar's radiative history and emission geometry. An end-to-end analysis - combining cosmological hydrodynamical simulations post-processed with a quasar emission model, realistic estimates of galaxy number densities, and instrument + telescope throughput - is conducted to explore the feasibility of detecting quasar light echoes. We present a new fully Bayesian statistical method that allows one to reconstruct quasar light echoes from thousands of individual low S/N transmission measurements. Armed with this machinery, we undertake an exhaustive parameter study and show that light echoes can be convincingly detected for luminous ($M_{1450} < -27.5\,\mathrm{mag}$ corresponding to $m_{1450} < 18.4\,\mathrm{mag}$ at $z\simeq 3.6$) quasars at redshifts $3<z_\mathrm{QSO}<5$, and that a relative precision better than $20\,\%$ on the quasar age can be achieved for individual objects, for the expected range of ages between 1 Myr and 100 Myr. The observational requirements are relatively modest - moderate resolution ($R\gtrsim750$) multi object spectroscopy at low $\rm{}S/N > 5$ is sufficient, requiring three hour integrations using existing instruments on 8m class telescopes.