VLT LBG Redshift Survey II: Interactions between galaxies and the IGM at z ~3

TL;DR

This study investigates the relationship between galaxies and the intergalactic medium at redshift ~3 by analyzing quasar spectra and galaxy distributions, revealing increased hydrogen absorption near galaxies and insights into galaxy-IGM interactions.

Contribution

It provides new measurements of the Lya-LBG cross-correlation at various scales, accounting for galaxy velocity dispersions, and examines the presence of transmission spikes and metal systems at z~3.

Findings

Lya absorption increases within 5 h^-1 Mpc of galaxies.

Lya-LBG correlation follows a power-law beyond 3 h^-1 Mpc.

No strong evidence for star-formation feedback-induced transmission spikes.

Abstract

We have measured redshifts for 243 z ~3 quasars in nine VLT VIMOS LBG redshift survey areas, each of which is centred on a known bright quasar. Using spectra of these quasars, we measure the cross-correlation between neutral hydrogen gas causing the Lya forest and 1020 Lyman-break galaxies at z ~3. We find an increase in neutral hydrogen absorption within 5 h^-1 Mpc of a galaxy in agreement with the results of Adelberger et al. (2003, 2005). The Lya-LBG cross-correlation can be described by a power-law on scales larger than 3 h^-1 Mpc. When galaxy velocity dispersions are taken into account our results at smaller scales (<2 h^-1 Mpc) are also in good agreement with the results of Adelberger et al. (2005). There is little immediate indication of a region with a transmission spike above the mean IGM value which might indicate the presence of star-formation feedback. To measure the galaxy velocity dispersions, which include both intrinsic LBG velocity dispersion and redshift errors, we have used the LBG-LBG redshift space distortion measurements of Bielby et al. (2010). We find that the redshift-space transmission spike implied in the results of Adelberger et al. (2003) is too narrow to be physical in the presence of the likely LBG velocity dispersion and is likely to be a statistical fluke. Nevertheless, neither our nor previous data can rule out the presence of a narrow, real-space transmission spike, given the evidence of the increased Lya absorption surrounding LBGs which can mask the spike's presence when convolved with a realistic LBG velocity dispersion. Finally, we identify 176 CIV systems in the quasar spectra and find an LBG-CIV correlation strength on scales of 10 h^-1 Mpc consistent with the relation measured at ~Mpc scales.