Nitrogen-enriched, highly-pressurized nebular clouds surrounding a super star cluster at cosmic noon

Abstract

Strong lensing offers a precious opportunity for studying the formation and early evolution of super star clusters that are rare in our cosmic backyard. The Sunburst Arc, a lensed Cosmic Noon galaxy, hosts a young super star cluster with escaping Lyman continuum radiation. Analyzing archival HST images and emission line data from VLT/MUSE and X-shooter, we construct a physical model for the cluster and its surrounding photoionized nebula. We confirm that the cluster is 4\,Myr old, is extremely massive M 107\,M and yet has a central component as compact as several parsecs, and we find a gas-phase metallicity Z=(0.220.03)\,Z. The cluster is surrounded by 105\,M of dense clouds that have been pressurized to P 109\, K\, cm-3 by perhaps stellar radiation at within ten parsecs. These should have large neutral columns N HI > 1022.5\, cm-2 to survive rapid ejection by radiation pressure. The clouds are likely dusty as they show gas-phase depletion of silicon, and may be conducive to secondary star formation if N HI > 1024\, cm-2 or if they sink further toward the cluster center. Detecting strong N III]λλ1750,1752, we infer heavy nitrogen enrichment ( N/O)=-0.21+0.10-0.11. This requires efficiently retaining 500\,M of nitrogen in the high-pressure clouds from massive stars heavier than 60\,M up to 4 Myr. We suggest a physical origin of the high-pressure clouds from partial or complete condensation of slow massive star ejecta, which may have important implication for the puzzle of multiple stellar populations in globular clusters.