The radii and limb darkenings of Alpha Centauri A and B - Interferometric measurements with VLTI/PIONIER

TL;DR

This study uses VLTI/PIONIER interferometry to precisely measure the limb darkening and radii of Alpha Centauri A and B, revealing discrepancies with existing stellar atmosphere models and highlighting the need for model improvements.

Contribution

First simultaneous near-infrared measurements of limb darkening and angular diameters of Alpha Centauri A and B using VLTI/PIONIER, providing new constraints for stellar atmosphere models.

Findings

Measured limb darkened angular diameters with high precision.

Derived stellar radii consistent with parallax measurements.

Found weaker limb darkening than predicted by models.

Abstract

The photospheric radius is one of the fundamental parameters governing the radiative equilibrium of a star. We report new observations of the nearest solar-type stars Alpha Centauri A (G2V) and B (K1V) with the VLTI/PIONIER optical interferometer. The combination of four configurations of the VLTI enable us to measure simultaneously the limb darkened angular diameter thetaLD and the limb darkening parameters of the two solar-type stars in the near-infrared H band (lambda = 1.65 microns). We obtain photospheric angular diameters of thetaLD(A) = 8.502 +/- 0.038 mas (0.43%) and thetaLD(B) = 5.999 +/- 0.025 mas (0.42%), through the adjustment of a power law limb darkening model. We find H band power law exponents of alpha(A) = 0.1404 +/- 0.0050 (3.6%) and alpha(B) = 0.1545 +/- 0.0044 (2.8%), which closely bracket the observed solar value (alpha_sun = 0.15027). Combined with the parallax pi = 747.17 +/- 0.61 mas recently determined, we derive linear radii of RA = 1.2234 +/- 0.0053 Rsun (0.43%) and RB = 0.8632 +/- 0.0037 Rsun (0.43%). The power law exponents that we derive for the two stars indicate a significantly weaker limb darkening than predicted by both 1D and 3D stellar atmosphere models. As this discrepancy is also observed on near-infrared limb darkening profile of the Sun, an improvement of the calibration of stellar atmosphere models is clearly needed. The reported PIONIER visibility measurements of Alpha Cen A and B provide a robust basis to validate the future evolutions of these models.