Multiple stellar populations in Magellanic Cloud clusters. V. The split main sequence of the young cluster NGC1866

TL;DR

This study reveals a split main sequence and extended main sequence turn-off in the young cluster NGC1866, indicating complex stellar populations with different ages and rotation rates, challenging simple stellar evolution models.

Contribution

First detailed analysis of split MS and eMSTO in NGC1866, showing the coexistence of rotating and non-rotating stars with different ages.

Findings

Blue MS is less populous, hosting about one-third of MS stars.

Red MS stars are more centrally concentrated.

The blue MS fraction decreases at brighter magnitudes.

Abstract

One of the most unexpected results in the field of stellar populations of the last few years, is the discovery that some Magellanic-Cloud globular clusters younger than ~400 Myr, exhibit bimodal main sequences (MSs) in their color-magnitude diagrams (CMDs). Moreover, these young clusters host an extended main sequence turn off (eMSTO) in close analogy with what is observed in most ~1-2 Gyr old clusters of both Magellanic Clouds. We use high-precision Hubble-Space-Telescope photometry to study the young star cluster NGC1866 in the Large Magellanic Cloud. We discover an eMSTO and a split MS. The analysis of the CMD reveals that (i) the blue MS is the less populous one, hosting about one-third of the total number of MS stars; (ii) red-MS stars are more centrally concentrated than blue-MS stars; (iii) the fraction of blue-MS stars with respect to the total number of MS stars drops by a factor of ~2 in the upper MS with F814W <~19.7. The comparison between the observed CMDs and stellar models reveals that the observations are consistent with ~200 Myr old highly-rotating stars on the red-MS, with rotation close to critical value, plus a non-rotating stellar population spanning an age interval between ~140 and 220 Myr, on the blue-MS. Noticeable, neither stellar populations with different ages only, nor coeval stellar models with different rotation rates, properly reproduce the observed split MS and eMSTO. We discuss these results in the context of the eMSTO and multiple MS phenomenon.