Radiative hydrodynamics simulations of red supergiant stars: I. interpretation of interferometric observations

TL;DR

This paper uses 3D radiative-hydrodynamics simulations to interpret interferometric observations of red supergiant stars, revealing large convective cells and surface inhomogeneities that challenge traditional smooth models.

Contribution

It demonstrates that 3D RHD simulations accurately reproduce interferometric data, providing new insights into surface granulation and convection in RSGs, surpassing simple symmetric models.

Findings

3D simulations fit interferometric data well

Large convective cells confirmed on Betelgeuse surface

Average limb-darkening coefficients derived

Abstract

Context. It has been suggested that convection in Red Supergiant (RSG) stars gives rise to large-scale granules causing observable surface inhomogeneities. This convection is also extremely vigorous, and suspected to be one of the causes of mass-loss in RSGs. It must thus be understood in details. Evidence has been accumulated that there are asymmetries in the photospheres of RSGs, but detailedstudies of granulation are still lacking. Interferometric observations offer an exciting possibility to tackle this question, but they are still often interpreted using smooth symmetrical limb-darkened intensity distributions, or very simple spotted ad hoc models. Aims. We explore the impact of the granulation on visibility curves and closure phases using the radiative transfer code OPTIM3D. We simultaneously assess how 3D simulations of convection in RSG with CO5BOLD can be tested against these observations. Methods. We use 3D radiative-hydrodynamics (RHD) simulations of convection to compute intensity maps at various wavelengths and time, from which we derive interferometric visibility amplitudes and phases. We study their behaviour with time, position angle, and wavelength, and compare them to observations of the RSG alpha Ori Results. We provide average limb-darkening coefficients for RSGs. We detail the prospects for the detection and characterization of granulation (contrast, size) on RSGs. We demonstrate that our RHD simulations provide an excellent fit to existing interferometric observation of alpha Ori, contrary to limb darkened disks. This confirms the existence of large convective cells on the surface of Betelgeuse.