Counting Little Red Dots at $z<4$ with Ground-based Surveys and Spectroscopic Follow-up

TL;DR

This study uses ground-based surveys to identify and analyze Little Red Dots (LRDs) at redshifts 2 to 4, revealing their declining number density and confirming their nature through spectroscopic follow-up, thus filling a gap in understanding their evolution.

Contribution

It presents the first ground-based search for LRDs at 2<z<4, providing new measurements of their number density and spectroscopic confirmation of their properties.

Findings

LRDs' number density decreases from 10^{-4.5} to 10^{-5.7} cMpc^{-3} between z>4 and z~2.

Spectroscopic follow-up confirms an accreting black hole in a low-mass galaxy at z=2.26.

Ground-based surveys are effective but require follow-up for contamination assessment.

Abstract

Little red dots (LRDs) are a population of red, compact objects discovered by JWST at $z>4$. At $4<z<8$, they are roughly 100 times more abundant than UV-selected quasars. However, their number density is uncertain at $z<4$ due to the small sky coverage and limited blue wavelength coverage of JWST. We present our ground-based search for LRDs at $2\lesssim z\lesssim4$, combining ultra-deep Hyper Suprime-Cam photometry and various (near-)infrared surveys within a total area of $\sim3.1\,\mathrm{deg^{2}}$. We find that for LRDs with $M_{5500}<-22.5$, their number density declines from $\sim10^{-4.5}\,\mathrm{cMpc^{-3}}$ at $z>4$ to $\sim10^{-5.3}\,\mathrm{cMpc^{-3}}$ at $2.7<z<3.7$ and $\sim10^{-5.7}\,\mathrm{cMpc^{-3}}$ at $1.7<z<2.7$. We also present the Magellan/FIRE spectrum of our first followed-up candidate, DEEP23-z2LRD1 at $z_\mathrm{spec}=2.26$, as a proof of concept for our sample selection. Similar to high-redshift LRDs, the spectrum of DEEP23-z2LRD1 exhibits broad H$\alpha$ emission with $\mathrm{FWHM}\approx2400\,\mathrm{km\,s^{-1}}$ and with nearly symmetric narrow H$\alpha$ absorption. Additionally, DEEP23-z2LRD1 has extremely narrow [OIII] lines with $\mathrm{FWHM}\approx140\,\mathrm{km\,s^{-1}}$, suggesting the presence of an accreting black hole in a low-mass host galaxy. Limited by the angular resolution of ground-based surveys, we emphasize that spectroscopic follow-ups are required to characterize the contamination fraction of this sample and pin down LRD number density at $z<4$.