Seven New Multiperiodic delta Scuti Variables Текст научной статьи по специальности «Физика»

Peremennye Zvezdy ( Variable Stars) 44, No. 2, 2024 Received 15 March; accepted 12 April.

DOI: 10.24412/2221-0474-2024-44-6-27

Seven New Multiperiodic 6 Scuti stars in Cygnus

A. Samokhvalov

Surgut, Russia, e-mail: sav@surgut.ru

In a small field in Cygnus, I discovered seven new DSCTC stars that demonstrate multiperiodic pulsations from V-band CCD observations. For each of these stars, from two to four reliable pulsation frequencies could be derived. The paper presents finding charts, frequency spectra, light curves for program stars. New high-quality multi-band observations of the discovered variable stars with larger telescopes are needed.

1 Introduction

Working on our program aimed at discoveries and studies of DSCT-type stars, we have discovered seven new DSCTC stars with signs of multiperiodic pulsations in a field in Cygnus. The main information about these stars is presented in Table 1. Their coordinates were drawn from the Gaia DR3 catalog (Gaia Collaboration, 2022). None of these stars are currently contained in the General Catalogue of Variable Stars (GCVS), see Samus et al. (2017), or in the AAVSO Variable Star Index (VSX), see Watson et al. (2006). However, they are marked VARIABLE in the Gaia DR3 catalog, see Gaia Data Release 3 (Gaia DR3), Variability (Eier et al., 2023). Infrared color indexes were drawn from 2MASS catalogue (Cutri et al., 2003).

_Table 1. New Variable Stars_

No. USNO-A2.0 RA, J2000.0 Dec, J2000.0 V J - H H - K J-K

1 1425-12331125 21h47m03!921 +53° 45'36'.'89 15™ 40 - 15™ 48 0m431 0m152 (T583

2 1425-12332333 21 47 07.191 +53 53 01.42 12.33 - 12.38 0.269 0.083 0.352

3 1425-12344159 21 47 39.389 +53 57 04.09 12.53 - 12.65 0.388 0.205 0.593

4 1425-12354548 21 48 08.497 +53 34 46.28 13.50 - 13.54 0.196 0.111 0.307

5 1425-12372223 21 48 58.784 +53 57 17.33 15.73 - 15.90 0.377 0.165 0.542

6 1425-12374410 21 49 05.085 +53 53 57.54 14.31 - 14.38 0.374 0.165 0.539

7 1425-12377701 21 49 14.504 +53 30 36.92 15.16 - 15.24 0.428 0.130 0.558

Based on VSX and 2MASS catalogs, we plot a population distribution diagram of DSCT stars (DSCT, DSCTC, and HADS-type stars) as a function of infrared colors, derived from 2MASS photometry (Fig. 1). Only stars with good 2MASS photometry (Qflg = AAA) and reliably defined variability types (without an uncertainty symbol ":" in VSX Type) are used. All the new variable stars reported here also possess the 2MASS quality flag Qflg = AAA. The new variable stars are located in this diagram near the maximum-density population core, in the green and blue zones. This position can be considered one of the signs of belonging to the DSCT variability type.

Figure 1.

Population distribution diagram of DSCT stars as a function of 2MASS infrared colors H — K(J — H) and J — K(J — H). New variable stars are marked in the diagram.

2 Observations, primary reduction and magnitude calibration

Our observations were carried out at the Caucasian Mountain Observatory (CMO) of M.V. Lomonosov Moscow State University (Shatsky et al., 2020) using the 0.25-m remote-controlled Ritchey-Chretien telescope, equipped with a SBIG STXL-6303e CCD Camera and a V filter. A total of 1120 images of the field with 600-second exposures were obtained on JD 2460187-2460325. Information about the number of images taken on each observing night is given in Table 2.

Table 2. Images taken on each observing night

HJD Images HJD Images HJD Images HJD Images HJD Images

2460187 12 2460211 27 2460237 33 2460259 33 2460302 4

2460188 9 2460212 4 2460238 30 2460261 13 2460308 23

2460189 15 2460216 25 2460240 29 2460275 5 2460309 6

2460190 14 2460218 32 2460246 21 2460277 31 2460310 9

2460198 22 2460223 9 2460248 35 2460281 37 2460311 21

2460202 18 2460225 33 2460249 32 2460282 15 2460314 14

2460203 16 2460226 6 2460250 19 2460283 36 2460316 18

2460207 23 2460230 30 2460253 31 2460286 5 2460320 22

2460208 25 2460231 30 2460254 15 2460287 5 2460321 21

2460209 26 2460232 30 2460256 12 2460298 28 2460325 17

2460210 28 2460233 30 2460257 11 2460299 25

For basic reductions for dark current, flat fields, and bias, and in order to remove hot pixels and cosmic rays hits, we used IRAF routines and proprietary software TheSkyX™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 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 V 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 3. Uncertainties in the oV column were derived from our photometry, the GAIA G, GBP , and Grp magnitudes were drawn from the corresponding catalog. Magnitudes in the "Calc. V" column were obtained using the equation:

Calc. V = Gaia G - [-0.02704 + 0.01424 x (GBP - GRP) - 0.2156 x (GBP - GRP)2 +

0.01426 x (Gbp - Grp)3], (1)

which is 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

GSC av GAIA Calc. V

G Gbp Grp

3968-2621 0.008 11.5102 12.5060 10.5323 12.2394

3968-3272 0.007 12.1790 12.5445 11.6340 12.3610

3968-3000 0.008 12.3394 12.5281 12.0156 12.4139

3968-2894 0.007 12.0446 12.3314 11.5923 12.1732

3968-2595 0.007 11.8378 12.1974 11.3031 12.0143

3968-2517 0.007 12.0227 12.2059 11.7003 12.0958

The observations are presented as a zip archive in the html version of this paper.

3 Results

To derive periods, we use Period04 software by Lenz and Breger (2005) that implements the discrete Fourier transform, very suitable for analysis of sine-shaped light curves of the pulsating variable stars with multiperiodicity.

We searched for periodic signals in our observations in the frequency range between 3 and 20 cycles per day that was selected following recommendations by Breger (2000). We continuously calculate significant frequencies, in the first iteration based on the original data, in the following iterations, using residuals instead, as long as the signal-to-noise ratio for the corresponding peak in the Fourier frequency spectrum exceeds 4. This is the empirical criterium obtained from the analysis of observations by Breger et al. (1993) and ensuring that the signal is a real feature. Parameters of the oscillations corresponding to the equation

m(t) = mmean + Ai sin(2n( fit + $*)) (2)

were determined by least squares and are collected in Table 4. The first column of this table gives the star's number in the USN0-A2.0 catalogue (Monet et al., 1998). The second column is the number of photometric measurements for the corresponding star. The third column is the average error of photometrical measurements. The fourth column contains the mean magnitude corresponding to Equation 2. Subsequent columns describe oscillations of each star. The column named Freqi contains numbers of significant

frequencies, which are presented in the next column. Columns marked and A contain the phase and amplitude of the ith oscillation. In the last column, we give the S/N ratio for the ith frequency, derived using the Period04 software. Only frequencies that satisfy the S/N > 4 criterion are kept.

For plotting light curves, Fourier spectra, and population distribution diagram, we used our own routines written in Python 3 programming language using the NumPy (Harris et al., 2020) and Matplotlib (Hunter, 2007) libraries.

Table 4. Detected frequencies of the new pulsating variable stars

USNO-A2.0 N Tfl&rror ^mean Oscillations

Freqi Frequency, d 1 Ai, mag SNR

1425-12331125 986 0.012 15.4382 fi /2 7.17082 8.46182 0.11158 0.33195 0.0213 0.0042 23.48 4.80

1425-12332333 1051 0.0018 12.3762 fl /2 h u 5.841265 5.503670 7.543690 6.930815 0.28593 0.91417 0.55110 0.05636 0.0123 0.0060 0.0039 0.0031 26.98 12.73 10.27 7.91

1425-12344159 1054 0.013 15.5964 fl /2 h u 11.349167 6.429910 11.116893 11.034570 0.16114 0.95664 0.30195 0.09757 0.0173 0.0163 0.0104 0.0066 15.00 12.13 8.99 5.63

1425-12354548 1057 0.0033 13.5234 fl /2 h U 17.932155 18.073310 13.329770 14.873727 0.85287 0.02408 0.57958 0.49255 0.0107 0.0037 0.0019 0.0018 30.26 10.46 5.45 5.13

1425-12372223 1059 0.0156 15.8190 h /2 h U 8.979444 8.713564 9.410159 17.201639 0.15165 0.07668 0.43088 0.96931 0.0285 0.0270 0.0196 0.0085 23.99 22.54 16.52 7.70

1425-12374410 1058 0.0054 14.3492 h /2 12.666880 12.963420 0.58088 0.33383 0.0159 0.0084 21.03 10.76

1425-12377701 1054 0.0097 15.2028 fl /2 h 17.573930 14.945790 14.717230 0.13065 0.93866 0.02628 0.0159 0.0080 0.0045 24.92 10.64 5.92

Our observations are available as a zip archive in the html version of this paper. 3.1 USNO-A2.0 1425-12331125

This is the faintest star in our sample, and we found only two significant frequencies for it. The second frequency has a very small amplitude and is very close to the lower reliability boundary, with the S/N ratio 4.8.

Figure 2 presents the frequency spectrum of USN0-A2.0 1425-12331125 and its theoretical light curve (solid curve) with superposed data points corresponding to individual observations.

The finding chart based on a POSS2 red plate is presented in Fig. 3.

The V-band phased light curve of USN0-A2.0 1425-12331125 with the following light elements:

Max HJD(TT) = 2460231.4118 + 0d 139454 x E is presented in Fig. 4.

USNO-A2.Q 1425-12331125

0.020 « 0.015 f. 0.010 0.005 0.000

3456789 10 11

frequency c/d

Synthesized and observed light curves

15.40 15.42 J 15.44 15.46 15.48

The frequency spectrum

fx___

/

llilli i, 111 In

lliUlt wrflTIWw w mm^kM

time(HID TT) 2460231+

Figure 2.

The frequency spectrum and light curve of USNO-A2.0 1425-12331125. In the bottom panel, the solid curve is the synthesized light curve and dots are observed data points.

USNO-A2.0 1425-12331125

# N- *

V i • * • *

t * . * • " *

* I* * ■ ,

• « » •

lt * * Var . 1 • • * ■

, E • , ■ S ■!- • • f » ♦ V ■ • . . .* .

• * • " • •

V k •

H «■ r * ' 4

m » •. V » - • i *

| • • • * «

• * • ; '

STScI POSS2 Red 9.16 x 9.16

Figure 3.

A finding chart for USNQ-A2.0 1425-12331125.

Phased light curve of USNÛ-A2.0 1425-12331125

Max(HJDTT) = 2460231.4118 + 0.139454xf Type = DSCTC

15.40

15.42 -

>

^ 15.44 £

15.46

15.48

• • : • • y . » • * • • • ; ; • y . » • •

it* v • •äst' •«*.• ».a • v- . . V • V' . * • M* 4 jfifte . * * ¿1 ÖS»«. - v • •• • v- . . v » V- . • * •v.* M* •*• N fc: ••• • • • i• •* < « ..

s * •va • £ • '■"vi i •

• M • • • M • •

0.00 0.25 0.50 0.75 1.00 1.25 1.50 1.75

Figure 4.

Phased light curve of USNQ-A2.0 1425-12331125.

2.00 Phase

3.2 USNO-A2.0 1425-12332333

Figure 5 presents the frequency spectrum of USN0-A2.0 1425-12332333 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.

USNO-A2.0 1425-12332333

The frequency spectrum

frequency c/d

Synthesized and observed light curves

time(HJD TT) 2460207+

Figure 5.

The frequency spectrum and light curve of USNO-A2.0 1425-12332333. In the bottom panel, the solid curve is the synthesized light curve and dots are observed data points.

The finding chart based on a POSS2 red plate is presented in Fig. 6.

The phased V-band light curve of USN0-A2.0 1425-12332333 with the following light elements:

Max HJD(TT) = 2460207.4150 + 0d 171196 x E is presented in Fig. 7.

3.3 USNO-A2.0 1425-12344159

The frequency spectrum of USN0-A2.0 1425-12344159 and its theoretical light curve (solid curve) with superposed data points corresponding to individual observations are given in Fig. 8. Light curve variations are easy to notice, they are reproduced with the model rather well.

The finding chart based on a P0SS2 red plate is presented in Fig. 9.

USNO-A2.Q 1425-12332333

» • * .:- .n • * v ■

* # 4 * • - *

■ * * • ♦ *

• * ■ • i |. •

E i 1 . *— f 9 " • »

m * * '

i • ■

• • - * ^ . * fc. *

• ■ e • •

4 • * k ■ • * »

STScI POSS2 Red 9.16 x 9.16

Figure 6.

A finding chart for USNQ-A2.0 1425-12332333.

Figure 7.

Phased light curve of USNQ-A2.0 1425-12332333.

USNO-A2.Q 1425-12344159

0.015 .1 0.010 10 0.005 0.000

4 6 8 10 12 14

frequency c/d

Synthesized and observed light curves

15.54 15.56 15.58

>

"5 15.60 E

15.62 15.64 15.66

0.5 1.0 1.5 2.0 2.5 3.0 3.5

time(HJD TT) 2460208+

Figure 8.

The frequency spectrum and light curve of USNQ-A2.0 1425-12344159. In the bottom panel, the solid curve is the synthesized light curve and dots are observed data points.

The frequency spectrum

USNQ-A2.0 1425-12344159

- / ' .

• * ♦ ' * ^ ■ , , ■ * . *

- . * Var . ; '•■■{■■ - • * * ' ■ * * " . ~ *' * . * a , . • * <t . i ^ • a » t • * ' • ' - • : " " - * .. . i • i « * » . . ■ 1 ■ * 9 * ■ ' " ■ ♦ *

STScI POSS2 Red 9.16x 9.16

Figure 9.

A finding chart for USNO-A2.0 1425-12344159.

The phased V-band light curve of USNO-A2.0 1425-12344159 with the following light elements:

Max HJD(TT) = 2460208.3956 + 0d088112 x E is presented in Fig. 10.

3.4 USNO-A2.0 1425-12354548

Figure 11 presents the frequency spectrum of USNO-A2.0 1425-12354548 and its theoretical light curve (solid curve) with superposed data points corresponding to individual observations.

The finding chart based on a POSS2 red plate is presented in Fig. 12.

The phased V-band light curve of USNO-A2.0 1425-12354548 with the following light elements:

Max HJD(TT) = 2460230.3458 + 0d055766 x E is presented in Fig. 13.

3.5 USNO-A2.0 1425-12372223

Figure 14 presents the frequency spectrum of USNO-A2.0 1425-12372223 and its theoretical light curve (solid curve) with superposed data points corresponding to individual observations.

Figure 10.

Phased light curve of USNO-A2.0 1425-12344159.

USNO-A2.Q 1425-12354548

0.010 „ 0.008 | 0.006 E 0.004 0.002 0.000

12 14 16 18 20 22

frequency c/d

Synthesized and observed light curves

13.50

13.51

"5 13.52 is E

13.53

13.54

0.4 0.6 0.8 1.0 1.2 1.4 1.6

time(HJD TT) 2460230+

Figure 11.

The frequency spectrum and light curve of USNO-A2.0 1425-12354548. In the bottom panel, the solid curve is the synthesized light curve and dots are observed data points.

The frequency spectrum

USNO-A2.0 1425-12354548

■ . * . N 1 mt • . * . • * * • . -. :

■ it • 1 • i ' * , * - -1. i? >:<\ . . • F, ' * -- -

* a a , ■' * ! |i * m • m I - ' . ■ * - • s ** • » .. , ' * * ■ • m ■ ' . . ■ - . ' *

* * , . - . . * 1 » 4 .

STScI POSS2 Red 9.16x 9.16

Figure 12.

A finding chart for USNO-A2.0 1425-12354548.

Figure 13.

Phased light curve of USNO-A2.0 1425-12354548.

Figure 14.

Frequency spectrum and light curve of USNO-A2.0 1425-12372223. In the bottom panel, the solid curve is the synthesized light curve and dots are observed data points.

USNO-A2.Q 1425-12372223

' N .. . ' t » *

■ . • ■ * * » ■ . * * • : ■ * * 1

- ' ♦ Var * " K 1 •■ ' E • . * *- • . . , * 4 < \ - ' - , *

■ »- - * * * + * * ■ ™ ■ » *

* • , ■ • ■ 4 ♦

STScI POSS2 Red 9.16^ 9.'16

Figure 15.

A finding chart for USNO-A2.0 1425-12372223.

The finding chart based on a POSS2 red plate is presented in Fig. 15.

The V-band phased light curve of USNO-A2.0 1425-12372223 with the following light elements:

Max HJD(TT) = 2460208.5268 + 0d0.111365 x E is presented in Fig. 16.

3.6 USNO-A2.0 1425-12374410

Figure 17 presents the frequency spectrum of USNO-A2.0 1425-12374410 and its theoretical light curve (solid curve) with superposed data points corresponding to individual observations.

The finding chart based on a POSS2 red plate is presented in Fig. 18.

The phased V-band light curve of USNO-A2.0 1425-12374410 with the following light elements:

Max HJD(TT) = 2460231.3404 + 0d078946 x E is presented in Fig. 19.

3.7 USNO-A2.0 1425-12377701

Figure 20 presents the frequency spectrum of USNO-A2.0 1425-12377701 and its theoretical light curve (solid curve) with superposed data points corresponding to individual observations.

Phased light curve of USNO-A2.0 1425-12372223

Max(HJDTT) = 2460208.5268 + 0.111365 x£ Type = DSCTC

5 15.800 "ci

¡2 15.825 15.850

• . • . • • . • . •

t \ • • • r * » • • v.-

* • . • • . r .y » • . • . . * ■0m

...... m ............. ...........

* * , • • „• j * : • ■ » i « * • • ! : v -* ... ...

....... • • • • • • •

0. 1 ! 1 DO 0.25 0.50 0.75 1. -1-i-1-1- DO 1.25 1.50 1.75 2.00

Phase

Figure 16.

Phased light curve of ÜSNQ-A2.0 1425-12372223.

0.0150 -

0.0100 -

a 0.0075 -i 0.0050 -

USNO-A2.0 1425-12374410

The frequency spectrum

r

14

T 16

T 18

frequency c/d

Synthesized and observed light curves

time(HJD TT) 2460231+

Figure 17.

The frequency spectrum and light curve of USNO-A2.0 1425-12374410. In the bottom panel, the solid curve is the synthesized light curve and dots are observed data points.

USNO-A2.Q 1425-12372223

* / i . • " N . - * * * * > .

... * 1 » . - t ' ; -

■ * ■ * ' • ♦.

" ''t - 1

f *. - - ' « *• ' * ■

* • • * . 4. *

- f i . * V t * - • .

STScI POSS2 Red 9.16 x 9.16

Figure 18.

A finding chart for USNO-A2.0 1425-12374410.

Phased light curve of USNC>-A2,0 1425-12374410

Max(HJDTT) = 2460231.3404 + 0.078946x£ Type = DSCTC

■ *. * *. t* * *j. * i* * •

• t j *J • ■ » t i • # • / i t fc J* I

• ».'i'I. .»J • "."I^ .«J «•

f «* ♦ «_ • • I >* »• * »

■ 4

--1--1-1-1--I-1-1-1-1--

0.00 0,25 0.50 0.75 1.00 1-25 1.50 1.75 2.00

Phase

Figure 19.

Phased light curve of USNO-A2.0 1425-12374410.

14.32 -

14.34 -

>

"5 £

14.36 -

14.33 -

USNO-A2.Q 1425-12377701

0.0150 0.0125

■S 0.0100

ij[ 0.0075 i 0.0050 0.0025 0.0000

12 13 14 15 16 17 18 19 20

frequency c/d

Synthesized and observed light curves

15.18

>

"5 15.20 15.22 15.24

0.5 1.0 1.5 2.0 2.5

time(HJD TT) 2460207+

Figure 20.

The frequency spectrum and light curve of USNO-A2.0 1425-12377701. In the bottom panel, the solid curve is the synthesized light curve and dots are observed data points.

The finding chart based on a POSS2 red plate is presented in Fig. 21.

USNO-A2.0 1425-12377701

i - ' . N * ■ V. " •' !* * i-i

- - * * " * . , ' . * 1 * j ( .* ■ Var . r

t • - 1 >■ *

' ' ' V , » 4 . t 1 , i • 1 i i • i * ■» v * * i

№ * ♦ ■ « * «

STScI POSS2 Red 9.16x 9.'16

Figure 21.

A finding chart for USNO-A2.0 1425-12377701.

The phased V-band light curve of USNO-A2.0 1425-12377701 with the following light elements:

Max HJD(TT) = 2460207.4569 + 0d056902 x E is presented in Figure 22.

4 Conclusion

We have found seven new pulsating DSCTC stars with reliable signs of multiperiodic pulsations. All detected frequencies correspond to reliable oscillations.

The fact that the studied seven DSCTC stars are located in a small field (0.42 square degrees) is a good reason to continue the search for stars with similar pulsation properties at low galactic latitudes, in adjacent star fields.

In order to check for the presence of possible additional frequencies and to verify pulsation mode identification, new precision photometry in several standard photometric bands is needed. We appeal to observers having access to large telescopes to continue observations of these interesting variable stars.

Acknowledgements: I would like to thank Prof. N. N. Samus for helpful discussion and the anonymous referee for suggested improvements of the manuscript.

References:

15.16 15.18

>

"5 15.20

IB

E

15.22 15.24

Phased light curve of USNQ-A2.0 1425-12377701

Max{HJDTT) = 2460207.4569 + 0.056902 xE Type = DSCT

1-1-1-1-1-1-1-1-r

0.00 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00

Phase

Figure 22.

Phased light curve of USNO-A2.0 1425-12377701.

Breger, M., 2000, ASP Conference Series, 210, 3

Breger, M., Stich, J., Garrido, R., et al., 1993, Astron. & Astrophys., 271, 482 Cutri, R. M., Skrutskie, M. F., van Dyk, S., et al., 2003, 2MASS All Sky Catalog of Point

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Standards, Centre de Donnees Astronomiques de Strasbourg, I/252 Samus, N. N., Kazarovets, E. V., Durlevich, O. V., Kireeva, N. N., Pastukhova, E. N.,

2017, Astron. Reports, 61, 80 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. V. & Lebedev, A. A., 2018, Astron. and Computing, 22, 28 Watson, C. L., Henden, A. A., & Price, A., 2007, Journal of the AAVSO, 35, 414