Reconstructing the genesis of a globular cluster system at a look-back time of 9.1 Gyr with the JWST

TL;DR

This study uses JWST data to analyze ancient globular cluster candidates in a galaxy 9.1 billion years ago, revealing rapid early chemical enrichment and potential links to modern Milky Way-like galaxies.

Contribution

First detailed analysis of globular cluster formation and chemical evolution in a galaxy at redshift 1.378 using JWST data, comparing observations with simulations.

Findings

Identification of old, metal-rich globular cluster candidates

Evidence of rapid early chemical enrichment in the galaxy

Comparison suggests the galaxy may be a progenitor of a Milky Way-like system.

Abstract

Using early-release data from the JWST, Mowla et al. and Claeyssens et al. recently measured various properties for gravitationally lensed compact sources (`sparkles') around the `Sparkler' galaxy at a redshift of 1.378 (a look-back time of 9.1 Gyr). Here, we focus on the Mowla et al. as they were able to break the age-metallicity degeneracy and derive independent ages, metallicities and extinctions for each source. They identified 5 metal-rich, old GC candidates (with formation ages up to $\sim$13 Gyr). We examine the age--metallicity relation (AMR) for the GC candidates and other Sparkler compact sources. The Sparkler galaxy, which has a current estimated stellar mass of 10$^9$ M$_{\odot}$, is compared to the Large Magellanic Cloud (LMC), the disrupted dwarf galaxy Gaia--Enceladus and the Milky Way (MW). The Sparkler galaxy appears to have undergone very rapid chemical enrichment in the first few hundred Myr after formation, with its GC candidates similar to those of the MW's metal-rich subpopulation. We also compare the Sparkler to theoretical AMRs and formation ages from the E-MOSAICS simulation, finding the early formation age of its GCs to be in some tension with these predictions for MW-like galaxies. The metallicity of the Sparkler's star forming regions are more akin to a galaxy of stellar mass $\ge$ 10$^{10.5}$ M$_{\odot}$, i.e. at the top end of the expected mass growth over 9.1 Gyr of cosmic time. We conclude that the Sparkler galaxy may represent a progenitor of a MW-like galaxy, even including the ongoing accretion of a satellite galaxy.