Abstract
We present first quantitative results of the surface magnetic field measurements in selected M-dwarfs based on detailed spectra synthesis conducted simultaneously in atomic and molecular lines of the FeH Wing-Ford $F^4\,\Delta-X^4\,\Delta$ transitions. A modified version of the Molecular Zeeman Library (MZL) was used to compute Land\'e g-factors for FeH lines in different Hund's cases. Magnetic spectra synthesis was performed with the Synmast code. We show that the implementation of different Hund's case for FeH states depending on their quantum numbers allows us to achieve a good fit to the majority of lines in a sunspot spectrum in an automatic regime. Strong magnetic fields are confirmed via the modelling of atomic and FeH lines for three M-dwarfs YZ~CMi, EV~Lac, and AD~Leo, but their mean intensities are found to be systematically lower than previously reported. A much weaker field ($1.7-2$~kG against $2.7$~kG) is required to fit FeH lines in the spectra of GJ~1224. Our method allows us to measure average magnetic fields in very low-mass stars from polarized radiative transfer. The obtained results indicate that the fields reported in earlier works were probably overestimated by about $15-30$\%. Higher quality observations are needed for more definite results.
Highlights
Magnetic fields in non-degenerate stars are found all across the Hertzsprung-Russell diagram, from hot high-luminous stars down to cool and ultra-cool dwarf
We present first quantitative results of the surface magnetic field measurements in selected M-dwarfs based on detailed spectra synthesis conducted simultaneously in atomic and molecular lines of the FeH Wing-Ford F4 Δ − X4 Δ transitions
Strong magnetic fields are confirmed via the modelling of atomic and FeH lines for three M-dwarfs YZ CMi, EV Lac, and AD Leo, but their mean intensities are found to be systematically lower than previously reported
Summary
Magnetic fields in non-degenerate stars are found all across the Hertzsprung-Russell diagram, from hot high-luminous stars down to cool and ultra-cool dwarf (see, for example, the review by Donati & Landstreet 2009, and references therein). These fields spawn a wide range of intensity and geometry, providing strong experimental ground for the theories of stellar magnetism. The search for alternatives ended up with molecular lines of FeH Wing-Ford F4 Δ − X4 Δ transitions around 0.99 μm (Valenti et al 2001; Reiners & Basri 2006) Some of these lines do show strong magnetic sensitivity, as seen, for instance, in the sunspot spectra (Wallace et al 1998)
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