부산대학교 도서관

Gyrochronology, a valuable tool for determining ages of low-mass stars where other techniques fail, relies on accurate calibration. We present a sample of 327 wide ($>$$100$\,au) white dwarf + main sequence (WD + MS) binary systems. Total ages of WDs are computed using all-sky survey photometry, Gaia parallaxes, and current hydrogen atmosphere WD models. Using a magnetic braking law calibrated against open clusters, along with assumptions about initial conditions and angular momentum transport, we construct gyrochrones to predict the rotation periods of the MS stars. Both data and models show that, near the fully convective boundary, MS stars with WD ages up to 7.5\,Gyr experience a rotation period increase by up to a factor of $\approx$$3$ within a $<50\,\mathrm{K}$ effective temperature range. We suggest that rapid braking at this boundary is driven by a sharp rise in the convective overturn timescale ($\tau_{\mathrm{cz}}$) caused by structural changes between partially and fully convective stars and the $^3 \textrm{He}$ instability occurring at this boundary. While the specific location in mass (or temperature) of this feature varies with model physics, we argue that its existence remains consistent. Stars along this feature exhibit rotation periods that can be mapped, within 1$\sigma$, to a range of gyrochrones spanning $\approx 6$\, Gyr. Due to current temperature errors ($\simeq$$50\,\mathrm{K}$), this implies that a measured rotation period cannot be uniquely associated to a single gyrochrone, implying that gyrochronology may not be feasible for M dwarfs very close to the fully convective boundary.
Comment: Submitted to ApJ. 31 pages, 17 figures, 2 tables