The first photometric and orbital period investigation of an extremely low mass ratio contact binary with a sudden period change TYC 4002-2628-1

Photometric observations for the totally eclipsing binary system TYC 4002-2628-1, were obtained between November 2020 and November 2021. To determine the stellar atmospheric parameters, a spectral image was taken with the 2.16 m telescope at National Astronomical Observatory of China (NAOC). TYC 400...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society 2022-10, Vol.517 (2), p.1928-1936
Main Authors: Guo, Di-Fu, Li, Kai, Liu, Fen, Li, Huai-Zhen, Xia, Qi-Qi, Gao, Xing, Gao, Xiang, Chen, Xu, Gao, Dong-Yang, Sun, Guo-You
Format: Article
Language:English
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Summary:Photometric observations for the totally eclipsing binary system TYC 4002-2628-1, were obtained between November 2020 and November 2021. To determine the stellar atmospheric parameters, a spectral image was taken with the 2.16 m telescope at National Astronomical Observatory of China (NAOC). TYC 4002-2628-1 is a low-amplitude (about 0.15 mag for Vband) short-period (0.3670495 d) contact eclipsing binary with a total secondary eclipse. Intrinsic light curve variations and the reversal of the O’Connell effect are detected in the light curves, which may be due to spot activity. Based on the photometric solutions derived from the multiband time series light curves, TYC 4002-2628-1 is an extremely low-mass ratio contact binary with a mass ratio of q ∼ 0.0482 and a fill-out factor of $f\sim 5{{\ \rm per\ cent}}$. By analysing the O− C variations, we find that its orbital period remains unchanged when BJD < 2458321. Then the orbital period changed suddenly around BJD 2458743 and has an increasing rate of $\mathrm{ d}P/\mathrm{ d}t=1.62\times {10^{-5}}\,\mathrm{ d}\cdot \mathrm{ yr}^{-1}=140\, \mathrm{ s}\cdot \mathrm{ century}^{-1}$. If confirmed, TYC 4002-2628-1 would be the contact binary with the highest orbital period increasing rate so far. By investigating the ratio of orbital angular momentum to the spin angular momentum (Jorb/$J_{\mathrm{ spin}}\, \lt\, 3$), the instability mass ratio (qinst/q = 1.84) and the instability separation (Ainst/A = 1.35), TYC 4002-2628-1 can be regarded as a merger candidate.
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/stac2811