Peremennye Zvezdy (Variable Stars) 44, No. 1, 2024 Received 1 January; accepted 26 January. |
Article in PDF |
DOI: 10.24412/2221-0474-2024-44-1-5
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Surgut, Russia, e-mail: sav@surgut.ru
I present a photometric study of the new UGSU cataclysmic variable star discovered as the transient 2023lmj. 160 -band observations of the object were obtained on JD 2460120-2460142. The period of superhumps is found to be . An overall light curve and average superhump profile are shown. |
The optical transient 2023lmj was detected on JD 2460119 (Sokolovsky et al., 2023). Several days later, Zhao & Gao (2023) obtained the spectrum of the transient and classified it as a cataclysmic variable star.
On the next night after discovering, I started my observations at the Caucasian Mountain Observatory (CMO) of M.V. Lomonosov Moscow State University (see Shatsky et al., 2020) using the 0.25-m remote-controlled Ritchey-Chretien telescope, equipped with a SBIG STXL-6303e CCD camera and a filter. A total of 978 images of the field with 600-second exposures were obtained on JD 2460120-2460257, but the star is visible only on 163 images, obtained on JD 2460120-2460142.
For basic reductions for dark current, flat fields, and bias, we used IRAF routines and proprietary software TheSkyXTM by Software Bisque Inc. For calibration, each observing night we obtained 16 bias frames, 16 dark frames, 16 flat fields, plus 16 dark frames corresponding to flat fields.
For photometry of the cataclysmic variable star, we applied VaST software by Sokolovsky & Lebedev (2018). All times in this paper are expressed in terrestrial time in accordance with IAU recommendations (resolution B1 XXIII IAU GA), with heliocentric corrections applied.
For plotting light curves, we used our own routines, written in Python 3 programming language using NumPy (Harris et al., 2020) and Matplotlib (Hunter, 2007) libraries.
For magnitude calibration in band, we use data of the GAIA DR3
catalogue. We restrict ourselves to single, relatively bright
stars, with no saturation of pixels for our CCD camera, no close
neighbors, and demonstrating no brightness variations during the
time interval of our observations. Detailed information about our
calibration stars is collected in Table 1. Uncertainties in the
column were derives from our photometry; GAIA ,
, and magnitudes were drawn from the
corresponding catalog. Magnitudes in the "Calc. " column were
obtained using the equation:
(1) |
GSC name | σV | GAIA | Calc. V | ||
G | GBP | GRP | |||
01051-01179 | 0.005 | 12.7355 | 12.9894 | 12.3245 | 12.8442 |
01051-01491 | 0.004 | 12.0755 | 12.8689 | 11.2027 | 12.6114 |
01585-00306 | 0.005 | 11.9655 | 12.9243 | 11.0048 | 12.6587 |
01584-00111 | 0.005 | 12.2554 | 12.7376 | 11.6132 | 12.5187 |
01051-01757 | 0.004 | 12.1621 | 12.5855 | 11.5643 | 12.3843 |
01051-00969 | 0.004 | 11.8089 | 12.5785 | 12.5785 | 12.3215 |
Observations of this star demonstrate rapid variations at a time scale of about with a peak-to-peak amplitude about on each observing night and with average level decreasing from () on JD 2460120 to () on JD 2460142. This photometric behavior is typical of cataclysmic variable stars of the UGSU subtype. Note that superhumps were already observed on the first night after the superoutburst, JD 2460120 (see the top light curve in Fig. 2). Unfortunately, because of the weather conditions, observations were interrupted after JD 2460142 and resumed on JD 2460159, when nothing brighter than () was visible at the position of the star.
Using Peranso software by Paunzen and Vanmunster (2016), we
performed a period analysis with discrete Fourier transform, very
suitable for analyzing sine-shaped superhump profiles of
cataclysmic variable stars. The best period of superhumps is
, typical of UGSU variable stars. The average
superhump profile with the following light elements:
Acknowledgements: I would like to thank N.N. Samus, S.V. Antipin, K.V. Sokolovsky, and S.A. Korotkii for helpful discussion.
References:
Hunter, J. D., 2007, Computing in Science & Engineering, 9, No. 3, 90
Harris, C. R., Millman, K. J., van der Walt, S. J., et al., 2020, Nature, 585, Issue 7825, 357
Gaia Collaboration, Vallenari, A., Brown, A. G. A., et al., 2022, ArXiv:2208.00211
Paunzen, E. & Vanmunster, T., 2016, Astron. Nachr., 337, Issue 3, 239
Shatsky, N., Belinski, A., Dodin, A., et al. 2020, in Ground-Based Astronomy in Russia. 21st Century, ed. I. I. Romanyuk, I. A. Yakunin, A. F. Valeev, & D. O. Kudryavtsev, p. 127
Sokolovsky, K., Korotkiy, S., Potapov, N., et al., 2023, Transient Discovery Report for 2023-06-23
Sokolovsky, K. V., Lebedev, A. A., 2018, Astron. & Computing, 22, 28
Zhao, J. & Gao, X., 2023, XOSS Transient Classification Report for 2023-06-25