Abstract
The advent of space photometry with CoRoT and Kepler has allowed for the gathering of exquisite and extensive time series for a wealth of main-sequence stars, including γ Doradus stars, whose detailed seismology was not achievable from the ground. γ Doradus stars present an incredibly rich pulsation spectra, with gravito-inertial modes, in some cases supplemented with δ Scuti-like pressure modes – for the hybrid stars – and, in many cases, with Rossby modes. The present paper aims to show that in addition to these modes which have been established in the radiative envelope, pure inertial modes that are trapped in the convective core can be detected in Kepler observations of γ Doradus stars thanks to their resonance with the gravito-inertial modes. We started by using a simplified model of perturbations in a full sphere of uniform density. Under these conditions, the spectrum of pure inertial modes is known from analytical solutions of the so-called Poincaré equation. We then computed coupling factors, which helped select the pure inertial modes which interact best with the surrounding dipolar gravito-inertial modes. Using complete calculations of gravito-inertial modes in realistic models of γ Doradus stars, we are able to show that the pure inertial and gravito-inertial resonances appear as “dips” in the gravito-inertial mode period spacing series at spin parameters that are close to those predicted by the simple model. We find the first evidence of such dips in the Kepler γ Doradus star KIC 5608334. Finally, using complete calculations in isolated convective cores, we find that the spin parameters of the pure inertial and gravito-inertial resonances are also sensitive to the density stratification of the convective core. In conclusion, we have discovered that certain dips in gravito-inertial mode period spacings that have been observed in some Kepler stars are, in fact, signatures of resonances with pure-inertial modes that are trapped in the convective core. This holds the promise that it would be possible to finally access the central conditions, namely, the rotation and density stratification, of intermediate-mass stars in the main sequence.
Highlights
Angular momentum transport in stellar radiative zones and its evolution over time is a major open issue in stellar physics
The present paper aims to show that in addition to these modes which have been established in the radiative envelope, pure inertial modes that are trapped in the convective core can be detected in Kepler observations of γ Doradus stars thanks to their resonance with the gravito-inertial modes
Using complete calculations in isolated convective cores, we find that the spin parameters of the pure inertial and gravito-inertial resonances are sensitive to the density stratification of the convective core
Summary
Angular momentum transport in stellar radiative zones and its evolution over time is a major open issue in stellar physics. With the purpose of bringing a main-sequence counterpart to the seismic constraint of rotation in evolved stars, γ Doradus stars g-modes monitored by Kepler have revealed near-core rotation rates in stars which are progenitors of red giants (Van Reeth et al 2016; Christophe et al 2018; Li et al 2019) This has paved the way for the testing of angular momentum transport models against near-core rotation measurements in main-sequence intermediate-mass stars. As for the more evolved stages, another – as yet to be found – mechanism seems to transport angular momentum from the innermost part of the radiative zone outwards Whether it leads to a rigidification of the rotation profile still remains unproven, but measurements in a handful of stars seem to suggest this is so (Kurtz et al 2014; Saio et al.2015; Murphy et al 2016; Van Reeth et al 2018; Li et al 2019). We investigate the dependency of these resonances on stellar characteristics in Sect. 4 and investigate the diagnosis potential of these resonances with regard to the measurement of rotation in the convective core
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