Investigation on the mass transferring near-contact binary TT Cet

Abstract First multi-colour complete light curves and low-resolution spectra of short-period eclipsing binary TT Cet are presented. The stellar atmospheric parameters of the primary star were derived through spectra fitting as: $T_{eff}=7\,091\pm124\,{\text{K}}$ , $\log g = 4.15\pm0.33\,{\text{cm}}/\text{s}^2$ , and $[Fe/H]=-0.23\pm0.04\,\text{dex}$ . The light curves were analysed using the Wilson–Devinney code. The photometric solution suggests that this target should be a near-contact binary with the primary component filling its critical Roche lobe (i.e. SD1-type NCB). The luminosity enhancement around the primary light maximum (phase 0.10–0.40) on the light curve was detected like other SD1-type NCBs, which could be caused by a hot spot near the facing surface of the secondary component due to mass transfer. Long-term decrease of the orbital period at a rate of $dP/dt=-5.01\,({\pm}0.06)\times 10^{-8}\,{{\text{d}} \cdot{yr}}^{-1}$ was detected by the O–C analysis, which supports the mass transfer from the primary to the secondary and is consistent with its primary filling configuration. No third body was found through the light curve and O–C analysis. TT Cet may locate in the broken contact stage predicted by the thermal relaxation oscillation theory (TRO) and will evolve to the contact stage eventually. It is another good observational example supporting the TRO theory. We have collected all known SD1-type NCBs with absolute parameters from the literatures. The relations of these parameters are summarised for these rare systems.

A Flare-Like Event from the Short-Period System XY UMa

10.1017/s025292110009641x ◽

1983 ◽

Vol 71 ◽

pp. 411-413

Author(s):

M. Zeilik ◽

R. Elston ◽

G. Henson ◽

P. Smith

Keyword(s):

Light Curve ◽

Light Curves ◽

Active System ◽

Primary Star ◽

Rs Cvn Stars ◽

Short Period ◽

Annual Changes ◽

Period System ◽

Photoelectric Observations

XY UMa (+55°1317, SA027143) is a short-period (P 0.48 d) cousin of the RS CVn stars. The primary star is G2-G5V; the secondary K5 (Geyer, quoted by Lorenzi and Scaltriti, 1977). Geyer (1977) has done the bulk of the observational work to date, including the first photoelectric observations. The rapid, annual changes in XY UMa's light curve, and the fact that the last published light curves was from the 1977 season convinced us to reobserve this active system.

Synthetic Light Curve Analysis of the Close Binary Systems BX Andromedae and RR Leporis

10.1017/s025292110008814x ◽

1989 ◽

Vol 107 ◽

pp. 359-360

Author(s):

R.G. Samec ◽

R.E. Fuller ◽

R. H. Kaitchuck ◽

B. B. Bookmyer ◽

D. R. Faulkner

Keyword(s):

Light Curve ◽

Binary Systems ◽

Thermal Relaxation ◽

Curve Analysis ◽

Light Curves ◽

Close Binary ◽

Comparison Star ◽

Short Time Scale ◽

Light Curve Analysis ◽

Short Period

AbstractUnpublished photoelectric observations of the systems BX And and RR Lep were subjected to light curve analysis using the Wilson-Devinney Code.The short-period eclipsing binary system BX And was observed on five nights in 1976 at the Morgan-Monroe station of the Goethe Link Observatory of Indiana University. The observations covering the eclipse portions of the light curves yielded four times of minimum light. A period study covering 89 years of observations confirms that a major period change took place about 1950. The system is suspected of being quite active on a short time scale. Standard magnitudes were derived for BX And and for the comparison star. The corrected color indices indicate that BX And and the comparison star BD+39° 476 are in the spectral range of F3-F5. The light curves, defined by 1092 observations in B, 1097 in V and 971 in the U filter are symmetric. The difference in the eclipse depths are quite large averaging 0.m46. A distinct de-reddening of the light curves occurs during the secondary eclipse. The first synthetic light curve solutions of the system were obtained. The solution of BX And indicates that the system consists of an F-type primary and a K-type secondary component in a state of shallow contact. This result is supported by the location of BX And on the Eggen period-color diagram for contact binaries. The large mass ratio, temperature disparity and period increase are found to be consistent with an early contact phase of thermal relaxation oscillations.

CSS J075415.6+191052 and NW Leo: two contact binaries at different evolutionary stages

Research in Astronomy and Astrophysics ◽

10.1088/1674-4527/ac3e5d ◽

2021 ◽

Author(s):

Xu-Dong Zhang ◽

Shengbang Qian ◽

Ergang Zhao ◽

Qijun Zhi ◽

Aijun Dong ◽

...

Keyword(s):

Relaxation Oscillation ◽

Thermal Relaxation ◽

Light Curves ◽

Secondary Component ◽

High Mass ◽

Dark Spot ◽

Left Shoulder ◽

Mass Ratio ◽

Convective Envelope ◽

Abstract Multi-color light curves of CSS J075415.6+191052 and NW Leo are presented and the photometric solutions suggest that CSS J075415.6+191052 is a low mass ratio (q=0.178) and slightly deep contact binary (f=34.9%), while NW Leo with high mass ratio (q=0.707) and shallow degree of contact (f=2.3%). For CSS J075415.6+191052, the RI light curves show weakening around the left shoulder of secondary minimum, which indicates that there may be a dark spot on the secondary component. However, the light curves of BV bands are totally symmetric. It is unreasonable if the dark spot is caused by magnetic activity or mass transfers between two components. Therefore, the weakening of the light curves in this contact binary is caused by something else. A possible explanation is mass transferring from primary component to common convective envelope through the inner Lagrangian point, and this part of the mass, for some reason, weakens RI bands of light from secondary component. O - C analysis of NW Leo reveals a cyclic period change with a modulation period of 4.7 years, which may be caused by the light travel time effect of a third body. The positions of CSS J075415.6+191052 and NW Leo in P - J_{orb}' diagram suggest that the former is more evolved, which is in agreement with their photometric solutions. In the current stage, CSS J075415.6+191052 is dominated by the angular momentum loss theory, but NW Leo mainly follow the thermal relaxation oscillation theory.

W Ursae Majoris Star Models: Observational Constraints

10.1017/s0252921100093842 ◽

1988 ◽

Vol 108 ◽

pp. 213-214

Author(s):

Albert P. Linnell

Keyword(s):

Binary Stars ◽

Relaxation Oscillation ◽

Thermal Relaxation ◽

Type Systems ◽

Light Curves ◽

Primary Minimum ◽

Star Models ◽

Massive Component ◽

Contact Binary Stars ◽

W Ursae Majoris stars can be understood as contact binary stars with a common envelope (Lucy 1968). They subdivide into two types: The A-type are earlier inspectral class than about F5, are believed to have radiative envelopes, and associate primary (deeper) eclipse minimum with transit eclipse. The W-type have spectral classes later than F5, are believed to have convectlve envelopes, and associate primary minimum with occultation eclipse. Controversy has surrounded the explanation of W-type light curves.Four distinct models have been introduced to describe the envelopes or photospheres of W UMa stars. (1) The Rucinski hot secondary model directly explains W-type light curves on a postulational basis. Since 70%-90% of the emitted radiation from the secondary (less massive) component is believed to reach the secondary via circulation currents from the primary, there is an apparent thermodynamic mystery why the secondary should be hotter. (2) The Lucy Thermal Relaxation Oscillation (TRO) model argues that the secondary component is perpetually out of thermal equilibrium and that the components are in contact only during part of a given TRO cycle. During contact the photosphere is supposed to be barotropic. In this case primary minimum always associates with transit eclipse, in disagreement with observation for W-type systems. (3) The Shu et al. thermal discontinuity (DSC) model also argues for a barotropic photosphere but differs from Lucy on the gravity brightening exponent. The changes are insufficient to produce W-type light curves, (4) Webbink (1977), and, separately, Nariai (1976), argue for a baroclinic envelope. If the baroclinicity extends to the photosphere there is a possibility that W-type l i g h t curves could be explained. In particular, the Webbink scenario produces a hot secondary.

The Eclipsing Binary WX Eridani

10.1017/s0252921100073656 ◽

1979 ◽

Vol 46 ◽

pp. 385

Author(s):

M.B.K. Sarma ◽

K.D. Abhankar

Keyword(s):

Light Curve ◽

Spectral Type ◽

Orbital Period ◽

Primary Component ◽

Light Curves ◽

Absorption Feature ◽

Primary Star ◽

Eclipsing Binary ◽

The Times ◽

Phase Angles

AbstractThe Algol-type eclipsing binary WX Eridani was observed on 21 nights on the 48-inch telescope of the Japal-Rangapur Observatory during 1973-75 in B and V colours. An improved period of P = 0.82327038 days was obtained from the analysis of the times of five primary minima. An absorption feature between phase angles 50-80, 100-130, 230-260 and 280-310 was present in the light curves. The analysis of the light curves indicated the eclipses to be grazing with primary to be transit and secondary, an occultation. Elements derived from the solution of the light curve using Russel-Merrill method are given. From comparison of the fractional radii with Roche lobes, it is concluded that none of the components have filled their respective lobes but the primary star seems to be evolving. The spectral type of the primary component was estimated to be F3 and is found to be pulsating with two periods equal to one-fifth and one-sixth of the orbital period.

The Eclipses of the Close Binary Star BE UMa

10.1017/s0252921100039464 ◽

1996 ◽

Vol 158 ◽

pp. 471-472

Author(s):

Janet H. Wood ◽

E. L. Robinson ◽

E.-H. Zhang

Keyword(s):

Light Curve ◽

High Speed ◽

Binary Star ◽

Light Curves ◽

Close Binary ◽

Primary Star ◽

Secondary Star ◽

Different Depths ◽

The Mean ◽

Close Binary Star

BE UMa is a close binary star, not transferring mass, with an extremely hot primary star irradiating the inner face of the cool secondary star. The light curve shows a large-amplitude, sinusoidal variation with a period of 2.29 d, and an eclipse that is centered on the minimum of the variation [1], [3]. According to [1], the eclipse is partial, not total. However, it has been argued [2] that the eclipse was really flat bottomed and thus total. This has important repercussions for the deduced model of the system. To resolve this issue we obtained simultaneous UBVR photometry of BE UMa using the Stiening 4-channel, high-speed photometer on the 82-inch telescope at McDonald Observatory. The mean light curves are shown in Fig. 1. The eclipse in all colours is round bottomed and partial. The different depths are caused by the different contribution from the red secondary star in each bandpass.

Long photometric cycle and disk evolution in the β Lyrae-type binary OGLE-BLG-ECL-157529

Astronomy and Astrophysics ◽

10.1051/0004-6361/202038110 ◽

2020 ◽

Vol 641 ◽

pp. A91

Author(s):

R. E. Mennickent ◽

J. Garcés ◽

G. Djurašević ◽

P. Iwanek ◽

D. Schleicher ◽

...

Keyword(s):

Mass Transfer ◽

Light Curve ◽

Hot Spot ◽

Mass Transfer Rate ◽

Variable Mass ◽

Bright Spot ◽

Relative Depth ◽

Disk Radius ◽

Long Cycle ◽

Stellar Component

Context. The subtype of hot algol semidetached binaries dubbed double periodic variables (DPVs) are characterized by a photometric cycle longer than the orbital one, whose nature has been related to a magnetic dynamo in the donor component controlling the mass transfer rate. Aims. We aim to understand the morphologic changes observed in the light curve of OGLE-BLG-ECL-157529 that are linked to the long cycle. In particular, we want to explain the changes in the relative depth of primary and secondary eclipses. Methods. We analyzed I and V-band OGLE photometric times series spanning 18.5 years and modeled the orbital light curve. Results. We find that OGLE-BLG-ECL-157529 is a new eclipsing Galactic DPV of orbital period 24d.8, and that its long cycle length decreases in amplitude and length during the time baseline. We show that the changes in the orbital light curve can be reproduced considering an accretion disk of variable thickness and radius that surrounds the hottest stellar component. Our models indicate changes in the temperatures of the hot spot and the bright spot during the long cycle, and also in the position of the bright spot. This, along with the changes in disk radius, might indicate a variable mass transfer in this system.

Variability of the Light Curves of the Close Binary GR Tauri

10.1017/s0252921100001585 ◽

2002 ◽

Vol 187 ◽

pp. 337-338

Author(s):

A. Yamasaki ◽

M. Takeda ◽

T. Yamauchi ◽

G. Takada ◽

S. Hattori

Keyword(s):

Binary System ◽

The State ◽

Light Curves ◽

Close Binary ◽

Eclipsing Binary ◽

Short Period ◽

AbstractVariability of the light curves of the short-period eclipsing binary system GR Tau (, almost-contact binary) is studied. It is found that GR Tau experienced both the state which is characterized by asymmetric light curves and the state characterized by symmetrical light curves.

FS Aur as a Permanent Superhump System

10.1017/s0252921100152340 ◽

2004 ◽

Vol 194 ◽

pp. 169-171

Author(s):

Gaghik H. Tovmassian ◽

Sergei V. Zharikov

Keyword(s):

Mass Transfer ◽

Transfer Rate ◽

Mass Transfer Rate ◽

Variable Mass ◽

Accretion Disc ◽

Light Curves ◽

Cataclysmic Variable ◽

Short Period ◽

Photometric Period ◽

Low Amplitude

AbstractWe discovered that the short period cataclysmic variable FS Aur at some epochs shows a photometric period close to the orbital. It exceeds the orbital period by ∽2%, which is a sign of the presence of a permanent superhump in the system. Superhumps tend to appear near short, low amplitude outbursts. We assume that FS Aur possesses a large thermally stable accretion disc and that the outburst may be due to the variable mass transfer rate. This, however, does not alter our previous explanation of yet another, 2.4 times longer than orbital, photometric period of FS Aur, found earlier, and persistently observed in its light curves.

Modelling of an Eclipsing RS CVn Binary: V405 And

Proceedings of the International Astronomical Union ◽

10.1017/s1743921311027347 ◽

2011 ◽

Vol 7 (S282) ◽

pp. 199-200

Author(s):

Krisztián Vida ◽

Katalin Oláh ◽

Zsolt Kővári

Keyword(s):

Light Curve ◽

Main Sequence ◽

Magnetic Activity ◽

Light Curves ◽

Stellar Structure ◽

Main Sequence Stars ◽

M Dwarfs ◽

Primary Star ◽

Convective Envelope ◽

Eclipsing Binary

AbstractV405 And is an ultrafast-rotating (Prot ≈ 0.46 days) eclipsing binary. The system consists of a primary star with radiative core and convective envelope, and a fully convective secondary. Theories have shown that stellar structure can depend on magnetic activity, i.e., magnetically active M-dwarfs should have larger radii. Earlier light curve modelling of V405 And indeed showed this behaviour: we found that the radius of the primary is significantly larger than the theoretically predicted value for inactive main sequence stars (the discrepancy is the largest of all known objects), while the secondary fits well to the mass-radius relation. By modelling our recently obtained light curves, which show significant changes of the spotted surface of the primary, we can find further proof for this phenomenon.