Bibcode
Birkby, Jayne; Nefs, Bas; Hodgkin, Simon; Kovács, Gábor; Sipőcz, Brigitta; Pinfield, David; Snellen, Ignas; Mislis, Dimitris; Murgas, F.; Lodieu, N.; de Mooij, Ernst; Goulding, Niall; Cruz, Patricia; Stoev, Hristo; Cappetta, Michele; Palle, E.; Barrado, David; Saglia, Roberto; Martin, Eduardo; Pavlenko, Yakiv
Referencia bibliográfica
Monthly Notices of the Royal Astronomical Society, Volume 426, Issue 2, pp. 1507-1532.
Fecha de publicación:
10
2012
Número de citas
59
Número de citas referidas
52
Descripción
We report the discovery of 16 detached M dwarf eclipsing binaries with J
< 16 mag and provide a detailed characterization of three of them,
using high-precision infrared light curves from the WFCAM Transit Survey
(WTS). Such systems provide the most accurate and model-independent
method for measuring the fundamental parameters of these poorly
understood yet numerous stars, which currently lack sufficient
observations to precisely calibrate stellar evolution models. We fully
solve for the masses and radii of three of the systems, finding orbital
periods in the range 1.5 < P < 4.9 d, with masses spanning
0.35-0.50 M&sun; and radii between 0.38 and 0.50
R&sun;, with uncertainties of ˜3.5-6.4 per cent in mass
and ˜2.7-5.5 per cent in radius. Close companions in short-period
binaries are expected to be tidally locked into fast rotational
velocities, resulting in high levels of magnetic activity. This is
predicted to inflate their radii by inhibiting convective flow and
increasing starspot coverage. The radii of the WTS systems are inflated
above model predictions by ˜3-12 per cent, in agreement with the
observed trend, despite an expected lower systematic contribution from
starspot signals at infrared wavelengths. We searched for correlation
between the orbital period and radius inflation by combining our results
with all existing M dwarf radius measurements of comparable precision,
but we found no statistically significant evidence for a decrease in
radius inflation for longer period, less active systems. Radius
inflation continues to exists in non-synchronized systems, indicating
that the problem remains even for very low activity M dwarfs. Resolving
this issue is vital not only for understanding the most populous stars
in the Universe, but also for characterizing their planetary companions,
which hold the best prospects for finding Earth-like planets in the
traditional habitable zone.
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Rafael
Rebolo López