The Physical Nature of the Off-centered Extended Emission Associated with the Little Red Dots

TL;DR

This study investigates the nature of extended emission near little red dots (LRDs) using JWST data, revealing off-centered blobs likely representing nebular gas illuminated by the LRDs, with implications for galaxy formation.

Contribution

It provides the first detailed spectral energy distribution analysis of off-centered extended emission around LRDs, confirming physical association and characterizing the gas properties.

Findings

Off-centered blobs are physically associated with LRDs.

Two blobs show strong [O III] emission indicating nebular gas.

Estimated halo mass accretion rate of 2-9 solar masses per year.

Abstract

A significant fraction of little red dots (LRDs) exhibit nearby extended emission of unknown origin. If physically associated with the LRD, this component may trace stellar emission from an off-centered host galaxy, neighboring companions, or nebular gas illuminated by the active nucleus. We investigate the detailed spectral energy distribution of the extended emission near four LRDs in the JWST UNCOVER and MegaScience surveys. We accurately decompose the extended emission from the dominant point source by simultaneously fitting the images in eight broad-band and nine medium-band filters. After considering both the results from photometric redshift fitting and the probability of galaxies at different redshift overlapping, we confirm that the off-centered blobs in three sources are physically associated with the LRDs, with two of them showing strong [\ion{O}{3}] $\lambda\lambda 4959,\,5007$ emission captured by the medium-band filters. While the spectral energy distributions of all three blobs can be modeled assuming star-forming galaxies with stellar mass $\sim 10^8\,M_{\odot}$, the exceptionally strong [\ion{O}{3}] emission of two sources is best interpreted as pure nebular emission from low-density ($n<10\, {\rm cm}^{-3}$), low-metallicity ($Z\approx 0.05\,Z_{\odot}$) gas photoionized by the ultraviolet radiation from the nearby LRD. Adopting LRD halo masses constrained by clustering measurements and theoretical considerations, we estimate a typical baryonic halo mass accretion rate of $\sim 2-9\, M_{\odot}\,{\rm yr}^{-1}$. If the halo accretion rate is sustained to $z=4$ and stars form with an efficiency of 10\%, the accreted gas would form a galaxy with stellar mass $\sim 10^9\,M_{\odot}$, potentially rendering them spatially resolved at lower redshift.