Origin of extended Main Sequence Turn Off in open cluster NGC 2355

TL;DR

This study investigates the extended Main Sequence Turn-Off in open cluster NGC 2355, concluding that stellar rotation rate spread, rather than dust extinction, primarily causes the eMSTO feature.

Contribution

It provides the first spectroscopic evidence linking stellar rotation rates to the eMSTO phenomenon in NGC 2355, emphasizing star-disc interactions as a key factor.

Findings

Stars in the red eMSTO have higher mean v sin i than blue eMSTO stars.

No significant dust extinction effects are observed in ultraviolet data.

Blue eMSTO stars are mostly located in the outer cluster regions.

Abstract

The presence of extended Main Sequence Turn-Off (eMSTO) in the open clusters has been attributed to various factors, such as spread in rotation rates, binary stars, and dust-like extinction from stellar excretion discs. We present a comprehensive analysis of the eMSTO in the open cluster NGC 2355. Using spectra from the Gaia-ESO archives, we find that the stars in the red part of the eMSTO have a higher mean v sin i value of 135.3$\pm$4.6 km s$^{-1}$ compared to the stars in the blue part that have an average v sin i equal to 81.3$\pm$5.6 km s$^{-1}$. This suggests that the eMSTO in NGC 2355 is possibly caused by the spread in rotation rates of stars. We do not find any substantial evidence of the dust-like extinction from the eMSTO stars using ultraviolet data from the Swift survey. The estimated synchronization time for low mass ratio close binaries in the blue part of the eMSTO suggests that they would be mostly slow-rotating if present. However, the stars in the blue part of the eMSTO are preferentially located in the outer region of the cluster indicating that they may lack low mass ratio close binaries. The spread in rotation rates of eMSTO stars in NGC 2355 is most likely caused by the star-disc interaction mechanism. The stars in the lower main sequence beyond the eMSTO region of NGC 2355 are slow-rotating (mean v sin i = 26.5$\pm$1.3 km s$^{-1}$) possibly due to the magnetic braking of their rotations.