MAMMOTH-Subaru IV. Large Scale Structure and Clustering Analysis of Ly$\alpha$ Emitters and Ly$\alpha$ Blobs at $z=2.2-2.3$

TL;DR

This study analyzes the large-scale structure and clustering of Ly$ ext{alpha}$ emitters and blobs at redshift 2.2-2.3, revealing their preference for overdense regions and their association with massive dark matter halos.

Contribution

It provides the first detailed clustering analysis of LAEs and LABs at this redshift, highlighting their distribution in overdense regions and their relation to dark matter halo mass.

Findings

79% of LABs are in overdense regions

Bright LABs have significantly steeper clustering slopes

LABs reside in massive dark matter halos (~10^{13} M_sun)

Abstract

We report the large scale structure and clustering analysis of Ly$\alpha$ emitters (LAEs) and Ly$\alpha$ blobs (LABs) at $z=2.2-2.3$. Using 3,341 LAEs, 117 LABs, and 58 bright (Ly$\alpha$ luminosity $L_{\rm Ly\alpha}>10^{43.4}$ erg s$^{-1}$) LABs at $z=2.2-2.3$ selected with Subaru/Hyper Suprime-Cam, we calculate the LAE overdensity to investigate the large scale structure at $z=2$. We show that $79\%$ LABs and $83\%$ bright LABs locate in overdense regions, which is consistent with the trend found by previous studies that LABs generally locate in overdense regions. We find that one of our 8 fields dubbed J1349 contains $39/117\approx33\%$ of our LABs and $22/58\approx38\%$ of our bright LABs. A unique and overdense $24'\times12'$ ($40\times20$ comoving Mpc$^2$) region (J1347 protocluster) has 12 LABs (8 bright LABs). By comparing to SSA22 that is one of the most overdense LAB regions found by previous studies, we show that the J1347 protocluster region has a higher bright LAB density than the SSA22 protocluster region with a $1\sigma$ significance. We calculate the angular correlation functions (ACFs) of LAEs and LABs in the unique J1349 field and fit the ACFs with a power-law function to measure the slopes. The bright LABs show a $5\sigma$ larger slope suggesting that bright LABs are more clustered than faint LAEs. Our LABs have a large galaxy bias of $\sim 5-7$, which suggests that LABs generally reside in more massive dark matter halos (halo masses $M \gtrsim 10^{13}$ M$_{\odot}$) than faint LAEs.