Origins of Carbon Dust in a JWST-Observed Primeval Galaxy at $z\sim$6.7

TL;DR

This study investigates the origins of hydrocarbon dust in a high-redshift galaxy at z~6.7 observed by JWST, exploring dust formation pathways and their implications for early universe galaxy evolution.

Contribution

It presents a model that reproduces observed spectral features and identifies two main pathways for hydrocarbon grain formation in early galaxies, considering dust production from supernovae and ISM accretion.

Findings

Dust can form via efficient ISM accretion or supernovae production.

PAHs are unlikely from AGB stars or grain shattering alone.

Galaxy's star formation history is complex and bursty.

Abstract

JADES-GS-z6-0, a high-redshift galaxy ($z \sim 6.7$) recently observed as part of the James Webb Space Telescope (JWST) Advanced Deep Extragalactic Survey (JADES), exhibits a distinct bump in its rest-frame ultraviolet (UV) spectrum indicative of a large quantity of hydrocarbon grains, a sign of rapid metal and dust enrichment in its interstellar medium (ISM). This galaxy serves as an ideal case for examining rapid dust formation processes in the early universe. We investigated diverse dust production channels from a possible maximal formation redshift of $z_{\rm form} \approx 17$, enabling dust contributions from asymptotic giant branch (AGB) stars over the longest possible timescale. Our model simultaneously reproduces key spectral features of JADES-GS-z6-0 such as its Balmer decrement, UV slope, and UV bump. The match is obtained by adopting a star-formation history in which a burst at $\sim 600$~Myr accounts for approximately 30\% of the galaxy's final stellar mass. Our findings indicate two pathways for the formation of hydrocarbon grains, such as polycyclic aromatic hydrocarbons (PAHs): (1) efficient dust accretion within the ISM, necessitating a low depletion of metals into dust grains from Type II supernovae ($\approx 10$\%), or (2) dust production predominantly by Type II supernovae, requiring a high depletion fraction ($\approx 73$\%) without dust accretion. We further demonstrate that PAHs are unlikely to originate solely from AGB stars or from shattering of large grains in the ISM. The evolution of the UV slope with redshift points to a complex and bursty star formation history for galaxies observed by JADES.