Abstract
Due to the space-borne missions CoRoT and Kepler , noteworthy breakthroughs have been made in our understanding of stellar evolution, and in particular about the angular momentum redistribution in stellar interiors. Indeed, the high-precision seismic data provide with the measurement of the mean core rotation rate for thousands of low-mass stars from the subgiant branch to the red giant branch. All these observations exhibit much lower core rotation rates than expected by current stellar evolution codes and they emphasize the need for an additional transport process. In this framework, internal gravity waves (herefater, IGW) could play a signifivative role since they are known to be able to transport angular momentum. In this work, we estimate the effciency of the transport by the IGW that are generated by penetrative convection at the interface between the convective and the radiative regions. As a first step, this study is based on the comparison between the timescale for the waves to modify a given rotation profile and the contraction/expansion timescale throughout the radiative zone of 1.3M⊙ stellar models. We show that IGW, on their own, are ineffcient to slow down the core rotation of stars on the red giant branch, where the radiative damping becomes strong enough and prevent the IGW from reaching the innermost layers. However, we find that IGW generated by penetrative convection could effciently modify the core rotation of subgiant stars as soon as the amplitude of the radial differential rotation between the core and the base of the convective zone is high enough, with typical values close to the observed rotation rates in these stars. This result argues for the necessity to account for IGW generated by penetrative convection in stellar modeling and in the angular momentum redistribution issue.
Highlights
Asteroseismology is a powerful tool to probe the internal structure of stars and the seismic data provided by the space-borne missions CoRoT and Kepler turn out to be a goldmine of information for the stellar evolution theory
The comparison of the wave-driven timescale with the contraction/dilatation timescale provides us with a first indication about the efficiency of the transport of angular momentum by IGW generated by penetrative convection throughout the radiative zone of a sequence of 1.3M models
Plume-induced IGW are shown to be inefficient on their own to slow down the core rotation as soon as the star starts ascending the red giant branch because of a too strong radiative damping near the H-burning shell, in agreement with previous works [e.g. 9]
Summary
Asteroseismology is a powerful tool to probe the internal structure of stars and the seismic data provided by the space-borne missions CoRoT and Kepler turn out to be a goldmine of information for the stellar evolution theory. The observations clearly show that the mean core rotation moderately increases on the subgiant branch [1, 2] before it strongly drops along the red giant branch [3]. Transport of angular momentum by meridional circulation and shear-induced mixing as included in the current stellar evolution codes are unable to counteract the strong acceleration due to the core contraction [e.g. 4, 5]. Another mechanism must be found to efficiently slow the core rotation of these stars. The role of the radial differential rotation amplitude on the transport by IGW is stressed out
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