|
Peremennye Zvezdy (Variable Stars) 41, No. 5, 2021 Received 7 September; accepted 29 September. |
Article in PDF |
|
DOI: 10.24412/2221-0474-2021-41-19-26
|
Possible Periodic Spot Activity of the New W UMa-type Variable GSC 3599-2569
S.Yu. Gorda1, Y.Yu. Vatolin2
- Kourovka Astronomical Observatory, Ural Federal
University, Mira st. 19, Yekaterinburg, 620002 Russia
- Ural Federal University, Mira st. 19, Yekaterinburg, 620002 Russia
| We present the results of long-term photometry (2009- 2021) of the new W UMa-type star GSC 3599-2569 discovered in 2013 at the Kourovka Observatory. We have found a change in the period of this eclipsing system. Based on more extensive observational data, the previously detected cyclical change in the brightness of the system, not associated with eclipses and caused by spot activity on the surface of the components, was confirmed. The length of this period has been specified. 11 new times of minima of GSC 3599-2569 are presented. |
The variability of the star GSC 3599-2569 (21
39
03
991,
+50
09
36
83, 2000, Gaia EDR3) was discovered in 2013
during a search for stars exhibiting irregular brightness
variations and located in the immediate vicinity of the young
variable star V645 Cyg (Sobolev et al., 2013).
Data analysis showed that brightness variations of GSC 3599-2569
were periodic,
, and the light
curve had a shape typical of short-period eclipsing variables of
the W UMa type (EW) with the same depths of minima (Gorda et al.,
2015).
The finding chart of the new variable is presented in Fig. 1. Two stars in the immediate vicinity of the variable are marked as C and C1, they were used as the comparison and check star, respectively. The data for these stars are listed in Table 1. Unfortunately, in Gorda et al. (2015), the designations of the comparison and check stars are mistakenly exactly the opposite. Table 1 of the present paper presents the correct designations.
 |
Fig. 1.
The finding chart for the new variable
GSC 3599-2569, which is a 16 |
7
17
Long-term photometric observations of V645 Cyg and its vicinities
were carried out from May 2009 to March 2018 with the AZT-3
reflector telescope (
m,
m)
and from February 2019 to April 2021 with the AstroSib-500RC
Ricci-Chretien telescope (
m, 
m) of
Kourovka Astronomical Observatory of the Ural Federal University.
Observations were carried out in the 
and 
filters,
implementing a system close to the Johnson-Cousins system, when
using Apogee Alta U6 CCD cameras with a Kodak KAF-1001E chip (
, 24 
m) and, since 2015, PL A230 of the FLI
company with an E2V 230-42 CCD chip (
, 15
m). The working field sizes were
and
, respectively for the first and second
telescopes.
The results presented in Gorda et al. (2015) were obtained on the base of observations carried out from 2009 to 2013. Since observations of the star V645 Cyg were continued till 2021, a large number of frames of this area were obtained. It was interesting to continue the study of GSC 3599-2569 as well.
One of the results of the study of this eclipsing binary, presented in Gorda et al. (2015), was the discovery of small-amplitude fluctuations of the star's total brightness, not associated with the phenomena of eclipses and tidal deformations of the components of the eclipsing system. At present, effects of extra-eclipse low-amplitude brightness changes of EW eclipsing binaries are explained with the presence of cool or hot spots on the surfaces of their components. This idea was first proposed by Mullan (1975), who suggested that the presence and change of the magnetic fields of the components can lead to activity cycles similar to those observed for the Sun. For example, in the papers by Binnenijk (1984), Djurasevic et al. (2001), and Zola et al. (2010), the extra-eclipse variations in the brightness of eclipsing W UMa systems are fully explained by the change in the area of spots on the surfaces of the components. Gorda (2020) discovered the cyclical nature of such brightness variations for the EW eclipsing variable AM Leo.
Cyclic brightness variations outside eclipses with a period of 940 days were also detected for the new variable star (Gorda et al., 2015). However, the derived period was comparable to the four-year observation interval of this star, which indicated insufficient reliability of the detected period. In order to confirm the presence of cyclic changes in the extra-eclipse brightness of the new close binary GSC 3599-2569 and to clarify the value of the period of these oscillations, we undertook this study.
| HJD | Type of |  |
(O-C)I | (O-C)II |
| 2450000+ | minimum | |||
| 4979.35820 | II | 0.5 | 0 00246 |
-000265 |
| 5035.36540 | II | 139.5 | 0.00458 | 0.00010 |
| 5040.40000 | I | 152.0 | 0.00275 | -0.00167 |
| 5089.35650 | II | 273.5 | 0.00517 | 0.00129 |
| 5092.37870 | I | 281.0 | 0.00552 | 0.00167 |
| 5153.21730 | I | 432.0 | 0.00407 | 0.00087 |
| 5176.18150 | I | 489.0 | 0.00216 | -0.00080 |
| 5223.12250 | II | 605.5 | 0.00365 | 0.00117 |
| 5399.39400 | I | 1043.0 | 0.00017 | -0.00061 |
| 5413.29580 | II | 1077.5 | 0.00143 | 0.00077 |
| 5414.30270 | I | 1080.0 | 0.00105 | 0.00040 |
| 5441.29710 | I | 1147.0 | 0.00019 | -0.00021 |
| 5442.30580 | II | 1149.5 | 0.00161 | 0.00121 |
| 5478.16370 | II | 1238.5 | 0.00014 | 0.00006 |
| 5478.36430 | I | 1239.0 | -0.00071 | -0.00080 |
| 5533.16060 | I | 1375.0 | -0.00075 | -0.00036 |
| 5533.36200 | II | 1375.5 | -0.00081 | -0.00042 |
| 5543.23470 | I | 1400.0 | 0.00049 | 0.00097 |
| 5570.22820 | I | 1467.0 | -0.00126 | -0.00056 |
| 5582.11530 | II | 1496.5 | -0.00013 | 0.00066 |
| 6205.21680 | I | 3043.0 | -0.00548 | -0.00071 |
| 6212.26750 | II | 3060.5 | -0.00578 | -0.00098 |
| 6274.11490 | I | 3214.0 | -0.00572 | -0.00063 |
| 6281.16600 | II | 3231.5 | -0.00561 | -0.00050 |
| 6517.27410 | II | 3817.5 | -0.00525 | 0.00071 |
| 6853.30450 | II | 4651.5 | -0.00532 | 0.00131 |
| 6912.33110 | I | 4798.0 | -0.00565 | 0.00103 |
| 7281.19800 | II | 5713.5 | -0.00673 | -0.00015 |
| 8125.10350 | I | 7808.0 | -0.00508 | -0.00157 |
| 8131.14890 | I | 7823.0 | -0.00339 | 0.00008 |
| 8225.42940 | I | 8057.0 | -0.00482 | -0.00194 |
| 8817.32030 | I | 9526.0 | 0.00508 | 0.00312 |
| 9119.30670 | II | 10275.5 | 0.00726 | 0.00209 |
| 9151.33580 | I | 10355.0 | 0.00468 | -0.00086 |
| 9194.24780 | II | 10461.5 | 0.00632 | 0.00026 |
| 9195.25250 | I | 10464.0 | 0.00373 | -0.00233 |
: calculated using a linear ephemeris;
(O-C)II: calculated using a quadratic ephemeris
Photometric processing of CCD frames obtained after 2013 was carried out in the same manner as described in Gorda et al. (2015). During the processing, 11 new times of minima of the eclipsing binary were obtained. All times of minima derived by us from 2009 to 2021 are given in the first column of Table 2. The new times of minima are placed at the bottom part of Table 2 and are separated from earlier values with a horizontal line. Calculations of the times of minima using the linear ephemeris from Gorda et al. (2015) did not show a satisfactory agreement with the times of minima obtained from observations after 2014. We have derived a new linear formula using all the times of minima of this star obtained by us. The O-C residuals, i.e. differences between the times of minima obtained from observations and those calculated using the new ephemeris, are given in the fourth column of Table 2.
 |
Fig. 2. O-C residuals from the new linear formula versus time; dots are O-C residuals; the solid curve is the approximation parabola. |
Figure 2 shows the O-C residuals for our new linear ephemeris versus time. We see that the O-C residuals are quite large and change with time in a nearly parabolic manner. This behavior of the O-C residuals indicates a change in the period of the eclipsing binary. Using a quadratic formula for calculating the times of minima permits to make the O-C residuals smaller by almost an order of magnitude (see the last column of Table 2). It appears from Fig. 3 that, in the case of calculating the times of minima using the quadratic formula, no systematic trend is found for the O-C residuals. The quadratic formula shown in Fig. 3 can be converted to a more convenient form for calculating photometric phases:
 |
(1) |
 |
(2) |
Thus, at this time, the period of GSC 3599-2569 is
. It is too early to discuss the true reasons for
the change in the period of the eclipsing binary. At least three
reasons can be suggested: mass transfer between the components,
mass loss by the system, and the presence of a third body in the
system.
After calculating the photometric phases, we found, as in the
previous study, that the portions (segments) of the light curves
of GSC 3599-2569 obtained on different nights at the same or
close photometric phases were shifted relative to one another
along the brightness axis. At the same time, the brightness
differences between the comparison star and the check star
remained unchanged within the observational errors (
) throughout the entire time interval of our
observations.
A new study of changes in the total brightness of GSC 3599-2569, not associated with the phenomena of eclipses and effects of tidal deformation of the components, was carried out using the method that we had previously used for similar purposes (Gorda et al., 2015; Gorda, 2020). The essence of the method is to calculate the night-average brightness difference between the light curve (segment of the light curve) obtained on a given night and the reference, theoretical curve synthesized on the basis of reliably established parameters of the eclipsing binary. For these purposes, we used theoretical light curves synthesized in the PHOEBE (Prsa & Zwitter, 2005) program using the orbital elements and parameters of the components of the eclipsing variable from Gorda et al. (2015). Specifically, the night-averaged shifts of the light curve portions relative to the theoretical curve were calculated using the following simple formula:
is the magnitude difference (variable
minus comparison star) for a single observation;
is the difference for the theoretical
light curve at the same photometric phase; and 
is the number
of observations made during the particular night. For the
observation interval from 2014 to 2021, 45 new values of 
were obtained in the and filters, respectively. For the
entire observation interval from 2009 to 2021, 74 values of
were obtained in the filter and 78, in the
filter.
We cheched the periodicity of the data series thus obtained using
the WINEFK code by V.P. Goranskij that implements the
Lafler-Kinman algorithm. The
parameter, its
large value indicating the presence of a periodicity, showed a
noticeable and fairly wide peak at the frequency corresponding to
the period
years. Figure 4 shows the
convolution of with the found period. The phases were
calculated using the ephemeris from the WINEFK program:
 |
(4) |
We see that the periodic nature of changes in is
clearly present. Since only one period is clearly traced in the
obtained data, in order to specify it, the data were approximated
with a harmonic function using the following relation:
 |
(5) |
and 
are scale factors, 
is the period,
and 
is the phase coefficient. The coefficients were
obtained by the nonlinear least-squares method. Then, the
coefficients and were manually corrected to provide a more
accurate correspondence of the approximating sinusoid to the
observational data. Since we do not know the true shape of the
variation profile, the sine fit was used only to
determine the brightness variation period. As a result, the period
was obtained, which only slightly differs
from that found using the WINEFK program.
 |
Fig. 5.
Variations of the extra-eclipse brightness
( |
We see from Fig. 5 that, after 2013 (
),
there is a significantly larger scatter of than during
the earlier time interval. This is due to the fact that the
observations of V645 Cyg during one night were restricted to
1.5-4 hours, since its brightness changed little during the
night. For this reason, only small portions of the light curve of
GSC 3599-2569 were observed every night, when only one side of
the spotted surfaces of the components was visible. This led to an
underestimation or overestimation of values, but in
general, since the observation process is quite random in time,
the general trend in recording changes corresponded to
reality. Ideally, for an accurate estimate of the
value, it is necessary to obtain the full light curve on each
observation night, which is extremely difficult, since the period
of this eclipsing system is about 10 hours. It should be noted
that during the time of our observations, the amplitude of the
cyclical variation of the star's extra-eclipse brightness was
slightly increasing (see Fig. 5). Perhaps this is due to the
presence of a second, longer cycle of changes in the magnetic
field of the system, similar to how it manifests itself in a
change in the degree of activity of the 11-year solar cycle.
However, this assumption requires additional research.
Thus, as a result of this study, from observations of GSC 3599-2569 acquired during a time interval of 12 years, the cycle nature of variations in the extra-eclipse brightness of the star was confirmed. The period of these changes, which can be caused by changes in the magnetic fields of the components of the eclipsing system, manifesting themselves in the degree of spotting of their surfaces, has been evaluated.
Acknowledgments
This work was supported by the Ministry of Education and Science of the Russian Federation within the framework of the research activities project No. FEUZ-2020-0030, as well as Decree 211 of the Government of the Russian Federation (contract No. 02.A03.21.0006).
References:
Binnenijk, L. 1984, Publ. Astron. Soc. Pacif. 96, 646
Djurasevic, G., Rovithis-Livaniou, H., Rovithis, P., et al. 2001, Astron. & Astrophys. 367, 840
Gorda, S. Yu., Lyaptsev, A.P., Sobolev, A.M. 2015, Astrophys. Bull. 70, 113
Gorda, S. Yu. 2020, Astronomy Reports 64, 922
Mullan, D.J., 1975, Astrophys. J. 198, 563
Prsa, A. and Zwitter, T. 2005, Astrophys.J., 628, 426
Sobolev, A.M., Gorda, S.Yu., Davidova, O.A., 2013, Inform. Bull. Var. Stars No. 6061
Zola, S., Gazeas, K., Kreiner, J.M., Ogloza, W. et al. 2010, Mon. Not. R. Astron. Soc. 408, 464