# The clustering of H$\beta$+[OIII] and [OII] emitters since $z \sim 5$:   dependencies with line luminosity and stellar mass

**Authors:** Ali Ahmad Khostovan, David Sobral, Bahram Mobasher, Philip N. Best,, Ian Smail, Jorryt Matthee, Behnam Darvish, Hooshang Nayyeri, Shoubaneh, Hemmati, John P. Stott

arXiv: 1705.01101 · 2018-05-02

## TL;DR

This study examines how the clustering of emission line galaxies at high redshift depends on line luminosity and stellar mass, revealing strong correlations with halo mass and potential quenching effects in massive halos.

## Contribution

It provides the first detailed analysis of clustering dependencies on line luminosity and stellar mass for high-redshift emitters, incorporating evolution of characteristic luminosity and halo mass models.

## Key findings

- Clustering length increases with line luminosity and redshift.
- Faintest emitters reside in low-mass halos, brightest in massive halos.
- Line luminosity dependency on halo mass is stronger than stellar mass dependency.

## Abstract

We investigate the clustering properties of $\sim 7000$ H$\beta$+[OIII] and [OII] narrowband-selected emitters at $z \sim 0.8 - 4.7$ from the High-$z$ Emission Line Survey. We find clustering lengths, $r_0$, of $1.5 - 4.0h^{-1}$ Mpc and minimum dark matter halo masses of $10^{10.7 - 12.1}\rm{M}_\odot$ for our $z = 0.8 - 3.2$ H$\beta$+[OIII] emitters and $r_0 \sim 2.0 - 8.3h^{-1}$ Mpc and halo masses of $10^{11.5 - 12.6}\rm{M}_\odot$ for our $z = 1.5 - 4.7$ [OII] emitters. We find $r_0$ to strongly increase both with increasing line luminosity and redshift. By taking into account the evolution of the characteristic line luminosity, $L^\star(z)$, and using our model predictions of halo mass given $r_0$, we find a strong, redshift-independent increasing trend between $L/L^\star(z)$ and minimum halo mass. The faintest H$\beta$+[OIII] emitters are found to reside in $10^{9.5}\rm{M}_\odot$ halos and the brightest emitters in $10^{13.0}\rm{M}_\odot$ halos. For [OII] emitters, the faintest emitters are found in $10^{10.5} \rm{M}_\odot$ halos and the brightest emitters in $10^{12.6}\rm{M}_\odot$ halos. A redshift-independent stellar mass dependency is also observed where the halo mass increases from $10^{11}\rm{M}_\odot$ to $10^{12.5} \rm{M}_\odot$ for stellar masses of $10^{8.5}\rm{M}_\odot$ to $10^{11.5}\rm{M}_\odot$, respectively. We investigate the interdependencies of these trends by repeating our analysis in a $L_\textrm{line} - \rm{M}_\textrm{star}$ grid space for our most populated samples (H$\beta$+[OIII] $z = 0.84$ and [OII] $z = 1.47$) and find that the line luminosity dependency is stronger than the stellar mass dependency on halo mass. For $L > L^\star$ emitters at all epochs, we find a relatively flat trend with halo masses of $10^{12.5 - 13}\rm{M}_\odot$ which may be due to quenching mechanisms in massive halos which is consistent with a transitional halo mass predicted by models.

## Full text

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## Figures

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## References

116 references — full list in the complete paper: https://tomesphere.com/paper/1705.01101/full.md

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Source: https://tomesphere.com/paper/1705.01101