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Disentangling discrepancies between stellar evolution theory and sub-solar mass stars. The influence of the mixing length parameter for the UV Psc binary
Authors: Lastennet, E.; J. Fernandes; Valls-Gabaud, D.; Oblak, E.
Ref.: Astronomy and Astrophysics 409, 611-618 (2003)
Abstract: Serious discrepancies have recently been observed between predictions of stellar evolution models in the 0.7-1.1 Msun mass range and accurately measured properties of binary stars with components in this mass range. We study one of these objects, the eclipsing binary UV Piscium, which is particularly interesting because Popper (\cite{popper1997}) derived age estimates for each component that differed by more than a factor of two. In an attempt to solve this significant discrepancy (a difference in age of 11 Gyr), we compute a large grid of stellar evolution models with the CESAM code for each component. By fixing the masses to their accurately determined values (relative error smaller than 1% for both stars), we consider a wide range of possible metallicities Z (0.01 to 0.05), and helium content Y (0.25 to 0.34) uncorrelated to Z. In addition, the mixing length parameter alphaMLT is left as another free parameter. We obtain a best fit in the Teff-radius diagram for a common chemical composition (Z, Y) = (0.012, 0.31), but a different MLT parameter alphaMLT a = 0.95 +/- 0.12(statistical)+0.30(systematic) and alphaMLT b = 0.65 +/- 0.07(stat)+0.10(syst). The apparent age discrepancy found by Popper (\cite{popper1997}) disappears with this solution, the components being coeval to within 1%. This suggests that fixing alphaMLT to its solar value ( ~ 1.6), a common hypothesis assumed in most stellar evolutionary models, may not be correct. Secondly, since alphaMLT is smaller for the less massive component, this suggests that the alphaMLT parameter may decrease with stellar mass, showing yet another shortcoming of the mixing length theory to explain stellar convection. This trend needs further confirmation with other binary stars with accurate data.
DOI: 10.1051/0004-6361:20031114
URL: cdsads.u-strasbg.fr