The JWST Unveils the Bimodal Nature of Lyman Alpha Emitters at 3 <z<7: Pristine versus Merger-Driven Populations

TL;DR

This study uses JWST imaging to analyze the merging galaxy populations among Lyman-alpha emitters at redshifts 3 to 7, revealing a bimodal distribution linked to galaxy mass and star formation activity.

Contribution

It identifies two distinct classes of LAEs—pristine and merger-driven—and demonstrates the role of mergers in their evolution during early cosmic times.

Findings

High merger fractions among LAEs vary with redshift, stellar mass, and UV brightness.

Bimodal distribution in stellar mass and sSFR distinguishes isolated from merger-driven LAEs.

Mergers significantly influence star formation and Lyman-alpha photon escape in early galaxies.

Abstract

We present a systematic study of merging galaxies among Lyman-alpha emitters (LAEs) using JWST/NIRCam high-resolution imaging data. From a large sample of 817 spectroscopically confirmed LAEs at $3<z<7$ in the GOODS-S field, we identify late-stage mergers and interacting systems with fractions of $39.4\%\pm2.5\%$ and $60.6\%\pm6.3\%$, respectively. These fractions exhibit significant redshift evolution and depend on both stellar mass ($M_*$) and UV magnitude ($M_{\rm UV}$), being most prevalent in massive ($\log(M_*/M_\odot)>8.5$) and bright ($M_{\rm UV}<-19.5$) systems. At fixed $M_*$ and $M_{\rm UV}$, we find negligible differences in the UV slope ($\beta$) between late-stage mergers and isolated LAEs; however, a clear bimodal distribution emerges in the $M_*$-sSFR plane, where isolated LAEs peak at $\log(M_*/M_\odot)\approx7.8$ and $\log({\rm sSFR/yr^{-1}})\approx-7.4$, and late-stage mergers peak at $\log(M_*/M_\odot)\approx8.6$ and $\log({\rm sSFR/yr^{-1}})\approx-7.6$. Our results reveal two evolutionary classes -- Pristine LAEs, low-mass ($M_*<10^{8.5}M_\odot$), isolated systems that represent early-stage galaxies with minimal merger interactions, and Merger-driven LAEs, massive ($M_*>10^{8.5}M_\odot$) systems in which mergers enhance star formation and facilitate the escape of Lyman-alpha photons or accrete pristine LAEs -- both of which are consistent with both observational and theoretical expectations and collectively demonstrate that mergers are a central driver of LAE evolution across the first two billion years.