Magnetic Fields of M Dwarfs from the Pleiades Open Cluster

TL;DR

This study measures magnetic fields of M-dwarfs in the Pleiades cluster, revealing correlations with rotation, radius inflation, and stellar activity, using high-resolution spectral analysis and modeling techniques.

Contribution

It introduces a novel application of MCMC modeling to derive magnetic filling factors for M-dwarfs in a cluster, linking magnetic fields to stellar properties and activity.

Findings

Positive correlation between magnetic fields and stellar rotation.

Magnetic fields are linked to radius inflation and spot coverage.

Stars with higher activity levels tend to have stronger magnetic fields.

Abstract

Average magnetic field measurements are presented for 62 M-dwarf members of the Pleiades open cluster, derived from Zeeman-enhanced Fe I lines in the H-band. An MCMC methodology was employed to model magnetic filling factors using SDSS-IV APOGEE high-resolution spectra, along with the radiative transfer code SYNMAST, MARCS stellar atmosphere models, and the APOGEE DR17 spectral line list. There is a positive correlation between mean magnetic fields and stellar rotation, with slow-rotator stars (Rossby number, Ro$>$0.13) exhibiting a steeper slope than rapid-rotators (Ro$<$0.13). However, the latter sample still shows a positive trend between Ro and magnetic fields, which is given by $<$B$>$ = 1604 $\times$ Ro$^{-0.20}$. The derived stellar radii, when compared with physical isochrones, show that on average, our sample shows radius inflation, with median enhanced radii ranging from +3.0$\%$ to +7.0$\%$, depending on the model. There is a positive correlation between magnetic field strength and radius inflation, as well as with stellar spot coverage, correlations that together indicate that stellar spot-filling factors generated by strong magnetic fields might be the mechanism that drives radius inflation in these stars. We also compare our derived magnetic fields with chromospheric emission lines (H$\alpha$, H$\beta$ and Ca II K), as well as with X-ray and H$\alpha$ to bolometric luminosity ratios, and find that stars with higher chromospheric and coronal activity tend to be more magnetic.