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An abrupt change in the stellar spin-down law at the fully convective boundary

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arxiv 2306.09119 v1 pith:UL7RM2IG submitted 2023-06-15 astro-ph.SR

An abrupt change in the stellar spin-down law at the fully convective boundary

classification astro-ph.SR
keywords convectivefullystarsabruptboundarychangelossmagnetic
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The importance of the existence of a radiative core in generating a solar-like magnetic dynamo is still unclear. Analytic models and magnetohydrodynamic simulations of stars suggest the thin layer between a star's radiative core and its convective zone can produce shearing that reproduces key characteristics of a solar-like dynamo. However, recent studies suggest fully and partially convective stars exhibit very similar period-activity relations, hinting that dynamos generated by stars with and without radiative cores hold similar properties. Here, using kinematic ages, we discover an abrupt change in the stellar spin-down law across the fully convective boundary. We found that fully convective stars exhibit a higher angular momentum loss rate, corresponding to a torque that is $\sim$ 2.25 times higher for a given angular velocity than partially convective stars around the fully convective boundary. This requires a dipole field strength that is larger by a factor of $\sim$2.5, a mass loss rate that is $\sim$4.2 times larger, or some combination of both of those factors. Since stellar-wind torques depend primarily on large-scale magnetic fields and mass loss rates, both of which derive from magnetic activity, the observed abrupt change in spin-down law suggests that the dynamos of partially and fully convective stars may be fundamentally different

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Cited by 1 Pith paper

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  1. RedDots: Magnetic field of the nearby active M dwarf GJ 729, and a search for companions

    astro-ph.SR 2026-07 conditional novelty 4.0

    GJ 729 exhibits a weak, evolving large-scale magnetic field (50-145 G) and a persistent ~7 d radial velocity signal that could be a ~1.5-2 Earth-mass planet or residual stellar activity.