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Peremennye Zvezdy (Variable Stars) 43, No. 3, 2023 Received 10 April; accepted 27 April. |
Article in PDF |
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DOI: 10.24412/2221-0474-2023-43-20-26
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Two new 
Scuti stars in Auriga
A. Samokhvalov
Surgut, Russia, e-mail: sav@surgut.ru
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I present my discovery and CCD observations of two new
small-amplitude Scuti (DSCTC) stars that demonstrate
multiperiodic pulsations. The paper contains detected frequencies,
light curves, finding charts, and other relevant information.
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1. Introduction
During observations of a field in Auriga, Kryachko et al. (2011) discovered several new variable stars. Here I report two additional new small-amplitude Scuti (DSCTC) stars in the
same field. The new variable stars are listed in Table 1. Their
coordinates were drawn from the Gaia DR3 catalog (Gaia
Collaboration, 2022). None of these stars are currently contained
in the AAVSO Variable Star Index (VSX). However, they are marked
VARIABLE in the Gaia DR3 catalog.
Table 1. New Variable Stars
| No. | Star | RA, J2000.0 | Dec, J2000.0 | V |
 |
|---|---|---|---|---|---|
| 1 | TYC 2414-127-1 |
 |
 |
 |
 |
| 2 | USNO-A2.0 1200-04164745 |
 |
 |
 |
 |
2. Observations and magnitude calibration
Our observations were carried out 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 with
and filters. Information about the observing
sets is given in Table 2.
Table 2. Observing sets
| No. |
|
Frames | Filter |
|
|||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| 1 | 9257 - 9305 | 356 |
|
300 | |||||||||||||||
| 2 | 9875 - 9987 | 1156 |
|
600 |
For basic reductions for dark current, flat fields, and bias, we used IRAF routines and proprietary software TheSkyXTM by Software Bisque Inc. For photometry of new pulsating stars, we applied VaST software by Sokolovsky and 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 magnitude calibration in the band, we use data of the
Tycho2 catalogue, and in the band, Gaia DR3. We use single,
relatively bright stars that do not produce saturation of pixels
of our CCD camera, have no close neighbors, and do not demonstrate
variability on the time interval of our observations. Detailed
information about calibration stars is given in Table 3. Values in
the 
and 
columns were obtained from our
photometry; Tycho 
, Tycho , Gaia 
, 
, and 
were drawn from the corresponding catalogues. Magnitudes in the
Calc. column were obtained using the equation:
 |
(1) |
To calculate magnitudes in the Calc. column, we use the
equation:
 |
|||
 |
(2) |
based on Table 5.9 of the Gaia Data Release 3, Documentation release 1.2
(https://gea.esac.esa.int/archive/documentation/GDR3/).
Table 3. Magnitudes of calibration stars
| Tycho name | σV | σRc | Tycho | Calc. V | Gaia | Calc. Rc | |||
| B | V | G | GBP | GRP | |||||
| TYC-2414-97-1 | 0.004 | 0.004 | 13.272 | 12.331 | 12.246 | 12.6844 | 12.7066 | 12.1160 | 12.5190 |
| TYC-2414-128-1 | 0.006 | 0.005 | 13.511 | 12.258 | 12.145 | 12.0363 | 12.4114 | 11.4907 | 11.8079 |
| TYC-2427-89-1 | 0.006 | 0.005 | 11.980 | 11.703 | 11.678 | 11.9705 | 12.1948 | 11.5968 | 11.8033 |
| TYC-2427-185-1 | 0.007 | 0.005 | 12.371 | 11.784 | 11.731 | 11.5736 | 11.8105 | 11.1838 | 11.3998 |
| TYC-2427-495-1 | 0.006 | 0.005 | 12.521 | 11.910 | 11.855 | 11.5991 | 11.9529 | 11.0720 | 11.3766 |
| TYC-2427-497-1 | 0.006 | 0.006 | 13.176 | 12.830 | 12.799 | 12.1947 | 12.5411 | 11.6725 | 11.9742 |
| TYC-2427-623-1 | 0.006 | 0.005 | 12.212 | 11.994 | 11.974 | 11.7696 | 12.0481 | 11.3194 | 11.5741 |
| TYC-2427-1263-1 | 0.006 | 0.004 | 12.460 | 11.896 | 11.845 | 11.9711 | 12.1749 | 11.6178 | 11.8138 |
Information on photometric measurements available for the two variable stars is given in Table 4. An archive of all observations is available online in the html version of this paper.
Table 4. Number of photometric measurements
| No. | Interval of observations JD 245... |
TYC 2414-127-1 | USNO-A2.0 1200-04164745 |
Filter |
|---|---|---|---|---|
| 1 | 9257 – 9305 | 355 | 355 | Rc |
| 2 | 9875 – 9987 | 1155 | 1155 | V |
| Total | 1510 | 1510 | ||
To derive periods, we use Period04 software by Lenz and Breger (2005) that implements discrete Fourier transform and is very suitable for analysis of sine-shaped light curves of multiperiodic pulsating variable stars.
3. Results
3.1. TYC 2414-127-1
 |
Fig. 1. Frequency spectrum and light curve of TYC 2414-127-1. In the bottom panel, the solid curve is the synthesized light curve and dots are observed data points. |
Observations of this star show rapid variations at a time scale of
about
with a peak-to-peak amplitude about
. We
searched for periodic signals in the observations using Period04
software in the frequency range between 3 and 20 cycles per day,
selected following recommendations by Breger (2000). Three
apparently significant frequencies were detected; their parameters
corresponding to the equation:
 |
(3) |
Table 4. Detected frequencies of TYC 2414-127-1
| Frequency, c/d |
 |
Amplitude, mag | |
|---|---|---|---|
 |
18.612620 | 0.348661 | 0.0081 |
 |
18.807620 | 0.416727 | 0.0045 |
 |
18.706380 | 0.779225 | 0.0038 |
Figure 1 presents the amplitude spectrum of TYC 2414-127-1 and its theoretical light curve (solid curve) with superposed data points corresponding to individual observations. Light curve variations are easy to notice, they are reproduced with the model rather well. The finding chart based on POSS2 red plate is presented in Fig. 2.
The phased light curve of TYC 2414-127-1 with the following light
elements:
in the
and filters is presented in Fig. 3.
3.2. USNO-A2.0 1200-04164745
 |
Fig. 4. Frequency spectrum and light curve of USNO-A2.0 1200-04164745. In the bottom panel, the solid curve is the synthesized light curve and dots are observed data points. |
Both observing sets reveal rapid variations at a time scale of
about
and with a peak-to-peak amplitude about
.
In Gaia DR3, Part 4, Variability by Gaia Collaboration (2022), the
variability type specified for this star is RS, but this object is
not present in the X-Ray 1RXS catalogue, see Voges at al. (1999).
Based on our photometry, we assume the DSCT type of variability.
To search for periodic signals in our observations, we use the
Period04 software in the frequency range between 3 and 20 cycles
per day, selected following recommendations by Breger (2000). Two
apparently significant frequencies were detected; their parameters
corresponding to Equation 3, determined by least squares, are
collected in Table 5.
Table 5. Detected frequencies of USNO-A2.0 1200-04164745
| Frequency, c/d |
|
Amplitude, mag | |
|---|---|---|---|
|
|
12.50865 | 0.655434 | 0.0180 |
|
|
11.92780 | 0.015228 | 0.0087 |
Figure 4 presents the amplitude spectrum of USNO-A2.0
1200-04164745 and its theoretical light curve (solid curve) with
superposed data points corresponding to individual observations.
Light curve variations are easy to notice, they are reproduced
with the model rather well. The finding chart based on POSS2 red
plate is presented in Figure 5. The phased light curve of
USNO-A2.0 1200-04164745 with the following light elements:
in the
and filters is presented in Fig. 6.
4. Conclusions
I have found two small-amplitude Scuti (DSCT) variables
in a field in Auriga, earlier studied by Kryachko et al. (2011).
The first of them, TYC 2414-127-1, turns out to be multiperiodic,
with three detected frequencies. For the second one, USNO-A2.0
1200-04164745, I found two frequencies. Finding charts and light
curves are presented for both stars.
Acknowledgements: I would like to thank N.N. Samus for helpful discussion.
References:
Breger, M., 2000, ASP Conference Series, 210, 3
ESA, 1997, The Hipparcos and Tycho Catalogues, ESA SP-1200, Vol. 1 (ESA97)
Gaia Collaboration, Vallenari, A., Brown, A. G. A., et al., 2022, ArXiv:2208.00211
Kryachko, T., Samokhvalov, A., Satovskiy, B., Peremennye Zvezdy Prilozhenie (Variable Stars Supplement), 2011, 11, No. 4
Lenz, P., Breger, M., 2005, Comm. in Asteroseismology, 146, 53
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, pp. 127-132
Sokolovsky, K. V., Lebedev, A. A., 2018, Astron. and Computing, 22, 28
Voges, W., Aschenbach, B., Boller, Th., et al. 1999, Astron. & Astrophys., 349, 389