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Register a new userHD 63021: Chromospheric Activity and Mass Transfer in a Close Binary
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Authors
D. G. Whelan
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Prompted by X-ray detections from multiple surveys, we investigated the A-type star HD 63021 and found that it is a double-lined spectroscopic binary with highly variable emission associated with the primary star. Analysis of our multi-epoch spectroscopic observations, the majority of which were carried out on small aperture telescopes, indicates a very short orbital period of just $2.9$ days, and a mass ratio M$_2$/M$_1$ of $0.23$. The A1 V star is a slow rotator, with a rotational speed of $sim34$ km/s. Assuming its mass is $2.3$ M$_{odot}$, the present-day secondary is an evolved star of $sim0.5$ M$_{odot}$ that nearly fills its Roche lobe. This secondary star rotates comparatively rapidly at $sim44$ km/s, and we see evidence that it is chromospherically active. Analysis of a photometric lightcurve from TESS reveals two strong periods, one at the orbital period for the system and another at half the orbital period. These findings suggest that HD 63021 is a close binary system undergoing mass transfer from the secondary star onto the primary star -- in all ways like an Algol eclipsing binary system, except without the eclipse. We discuss the systems mass transfer, which is not steady but seems to run in fits and bursts, and infer the systems basic physical properties from an orbital parameter study, the Roche lobe geometry, and its extant X-ray emission.
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