Spatially Resolved Physical Properties of Young Star Clusters and Star-forming Clumps in the Brightest z>6 Galaxy, the Strongly Lensed Cosmic Spear at z=6.2

TL;DR

This study uses JWST imaging and spectroscopy to analyze the spatially resolved properties of young star clusters and star-forming regions in the brightest known z>6 galaxy, revealing extremely dense, young, and compact stellar systems with implications for early galaxy evolution.

Contribution

First detailed spatially resolved analysis of star clusters in a z>6 galaxy using JWST, revealing their sizes, masses, densities, and star formation characteristics.

Findings

Star clusters have effective radii of ~5 pc and stellar masses of 10^6-10^7 M_sun.

Clusters are very young (~5-9 Myr) but dynamically older, indicating gravitational binding.

Central star-forming regions show slightly suppressed ionizing photon efficiency, suggesting potential Lyman continuum escape channels.

Abstract

We present spatially resolved analysis of stellar populations in the brightest $z>6$ galaxy known to date (AB mag 23), the strongly lensed MACS0308$-$zD1 (dubbed the ``Cosmic Spear'') at $z_{\rm spec}=6.2$. New JWST NIRCam imaging and high-resolution NIRSpec IFU spectroscopy span the rest-frame ultraviolet to optical. The NIRCam imaging reveals bright star-forming clumps and a tail consisting of three distinct, extremely compact star clusters that are multiply-imaged by gravitational lensing. The star clusters have effective radii of $R_{\rm{eff}} \sim 5$ pc, stellar masses of $M_{*} \sim 10^{6}-10^{7}\,M_{\odot}$, and high stellar mass surface densities of $\Sigma_{*} > 10^{4}\,M_{\odot}~\rm{pc}^{-2}$. While their stellar populations are very young ($\sim 5-9$ Myr), their dynamical ages exceed unity, consistent with the clusters being gravitationally bound systems. Placing the star clusters in the size vs.~stellar mass density plane, we find they occupy a region similar to other high-redshift star clusters within galaxies observed recently with JWST, being significantly more massive and denser than local star clusters. Spatially resolved analysis of the brightest clump reveals a compact, intensely star-forming core. The ionizing photon production efficiency ($\xi_{\rm{ion}}$) is slightly suppressed in this central region, potentially indicating a locally elevated Lyman continuum escape fraction facilitated by feedback-driven channels.