THE MASS-DEPENDENCE OF ANGULAR MOMENTUM EVOLUTION IN SUN-LIKE STARS

To better understand the observed distributions of the rotation rate and magnetic activity of Sun-like and low-mass stars, we derive a physically motivated scaling for the dependence of the stellar wind torque on the Rossby number. The torque also contains an empirically derived scaling with stellar...

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Published inAstrophysical journal. Letters Vol. 799; no. 2; pp. L23 - 6
Main Authors Matt, Sean P., Brun, A. Sacha, Baraffe, Isabelle, Bouvier, Jérôme, Chabrier, Gilles
Format Journal Article
LanguageEnglish
Published United States Bristol : IOP Publishing 01.02.2015
Subjects
ANGULAR MOMENTUM
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
DIAGRAMS
Envelopes
MAGNETIC FIELDS
Magnetic properties
MAGNETOHYDRODYNAMICS
MAIN SEQUENCE STARS
MASS
Rotating
ROTATION
Sciences of the Universe
STAR EVOLUTION
Stars
Stellar mass
STELLAR WINDS
TORQUE
stars: winds
stars: magnetic field
stars: late-type
stars: evolution
magnetohydrodynamics: MHD
outflows
stars: rotation
Astrophysics - Solar and Stellar Astrophysics
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Summary:To better understand the observed distributions of the rotation rate and magnetic activity of Sun-like and low-mass stars, we derive a physically motivated scaling for the dependence of the stellar wind torque on the Rossby number. The torque also contains an empirically derived scaling with stellar mass (and radius), which provides new insight into the mass-dependence of stellar magnetic and wind properties. We demonstrate that this new formulation explains why the lowest mass stars are observed to maintain rapid rotation for much longer than solar-mass stars, and simultaneously why older populations exhibit a sequence of slowly rotating stars, in which the low-mass stars rotate more slowly than solar-mass stars. The model also reproduces some previously unexplained features in the period-mass diagram for the Kepler field, notably: the particular shape of the "upper envelope" of the distribution, suggesting that ~95% of Kepler field stars with measured rotation periods are younger than ~4 Gyr; and the shape of the "lower envelope," corresponding to the location where stars transition between magnetically saturated and unsaturated regimes.
Bibliography:ObjectType-Article-1
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content type line 23
ISSN:2041-8213
2041-8205
2041-8213
DOI:10.1088/2041-8205/799/2/L23