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The Cepheid mass discrepancy and pulsation-driven mass loss

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arxiv 1104.1638 v1 pith:YVJJZVA2 submitted 2011-04-08 astro-ph.SR

The Cepheid mass discrepancy and pulsation-driven mass loss

classification astro-ph.SR
keywords masscepheiddiscrepancylossevolutionpulsation-drivenstellarconvective
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Context. A longstanding challenge for understanding classical Cepheids is the Cepheid mass discrepancy, where theoretical mass estimates using stellar evolution and stellar pulsation calculations have been found to differ by approximately 10 - 20%. Aims. We study the role of pulsation-driven mass loss during the Cepheid stage of evolution as a possible solution to this mass discrepancy. Methods. We computed stellar evolution models with a Cepheid mass-loss prescription and various amounts of convective core overshooting. The contribution of mass loss towards the mass discrepancy is determined using these models, Results. Pulsation-driven mass loss is found to trap Cepheid evolution on the instability strip, allowing them to lose about 5 - 10% of their total mass when moderate convective core overshooting, an amount consistent with observations of other stars, is included in the stellar models. Conclusions. We find that the combination of moderate convective core overshooting and pulsation-driven mass loss can solve the Cepheid mass discrepancy.

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