Abstract
EW-type eclipsing binaries (hereafter called EWs) are strong interacting systems in which both component stars usually fill their critical Roche lobes and share a common envelope. Numerous EWs were discovered by several deep photometric surveys and there were about 40 785 EW-type binary systems listed in the international variable star index (VSX) by 2017 March 13. 7938 of them were observed with LAMOST by 2016 November 30 and their spectral types were identified. Stellar atmospheric parameters of 5363 EW-type binary stars were determined based on good spectroscopic observations. In the paper, those EWs are cataloged and their properties are analyzed. The distributions of orbital period (P), effective temperature (T), gravitational acceleration (log(g)), metallicity ([Fe/H]) and radial velocity (RV) are presented for these observed EW-type systems. It is shown that about 80.6% of sample stars have metallicity below zero, indicating that EW-type systems are old stellar populations. This is in agreement with the conclusion that EW binaries are formed from moderately close binaries through angular momentum loss via magnetic braking that takes a few hundred million to a few billion years. The unusually high metallicities of a few percent of EWs may be caused by contamination of material from the evolution of unseen neutron stars or black holes in the systems. The correlations between orbital period and effective temperature, gravitational acceleration and metallicity are presented and their scatters are mainly caused by (i) the presence of third bodies and (ii) sometimes wrongly determined periods. It is shown that some EWs contain evolved component stars and the physical properties of EWs mainly depend on their orbital periods. It is found that extremely short-period EWs may be older than their long-period cousins because they have lower metallicities. This reveals that they have a longer timescale of pre-contact evolution and their formation and evolution aremainly driven by angular momentum loss via magnetic braking.
Export citation and abstract BibTeX RIS
1. Introduction
EW-type eclipsing binaries (hereafter called EWs) usually consist of two ellipsoidal FGK dwarfs that are in contact with each other and share a common convective envelope (CCE) that is lying between the inner and outer critical Roche-lobe surfaces. They areW Ursae Majoristype eclipsing variables with periods shorter than one day. Their light variation is continuous and it is impossible to specify the exact times of onset and end of eclipses. Their light amplitudes are usually < 0.8mag in V and the depths of the primary and secondary minima are almost equal (e.g., Samus et al. 2017). This indicates that the two components possess almost identical temperature and are in thermal contact in spite of different component masses. This kind of star system is different from EB-type binaries whose depths of primary and secondary minima are not equal and they are not in thermal contact. EW-type binaries are usually detected in older open clusters and globular clusters (e.g., Kaluzny & Rucinski 1993), but they are absent in young stellar clusters (e.g., Rucinski 1998). Based on these observational facts, some investigators assumed that EW-type binaries form from short-period detached binaries through angular momentum loss via magnetic braking (e.g., Guinan & Bradstreet 1988; Bradstreet & Guinan 1994) and will merge into rapidly rotating single stars (e. g., Zhu et al. 2016). The timescale of pre-contact evolution is from a few hundred million to a few billion years. However, how EWbinaries form is still unknown. It is possible that third bodies may play an important role in the origin of EWs by removing angular momentumfrom the central binary through early dynamical interaction and/or later evolution (e.g. Qian et al. 2014, Zhu et al. 2013a).
Thanks to several photometric surveys, such as the Catalina Sky Survey1 (CSS, Drake et al. 2009, 2014), the asteroid survey LINEAR2 (Palaversa et al. 2013), All Sky Automated Survey3 (ASAS, Pojmanski 1997; Pojmanski et al. 2005) and Northern Sky Variability Survey4 (NSVS, Woźniak et al. 2004), a large number of EW binaries have been discovered. Since the data on variable stars including EWs are constantly being updated, the mission of VSX5 (the international variable star index, Watson 2006) is to compile all of the new information together in a single data repository and provide tools necessary for the controlled and secure revision of the data. 40 785 EW-type binary systems were listed in VSX by 2017 March 13. Among the 40 785 EWs, the orbital periods of 40 646 systems were included. Those survey data are very useful for understanding the photometric properties of EW binaries. However, statistical spectroscopic properties of those sample stars are unclear because of the lack of spectral surveys. The light curves of many EW binaries have been observed recently, but their spectral types are generally unknown.
The Large Sky Area Multi-Object Fiber Spectroscopic Telescope (LAMOST, also called the Guo Shou Jing Telescope) is a special telescope with an effective aperture of about 4 meters that is located at Xinglong Station, administered by National Astronomical Observatories, Chinese Academy of Sciences. It has a field of view of 5 degrees and can simultaneously obtain the spectra of about 4000 stars with low-resolution of about 1800 in one exposure (Wang et al. 1996; Cui et al. 2012). The wavelength range of LAMOST is from 3700 to 9000 Å and is divided into two arms, i.e., a blue arm (3700–5900 Å) and a red arm (5700–9000 Å). The final spectrum of each target is obtained by merging several exposures. Huge amounts of spectroscopic data have been obtained (e.g., Zhao et al. 2012; Luo et al. 2012, 2015).
In recent LAMOST data releases, about 19.5% of EW-type binaries (7938) in VSX were observed by the LAMOST survey from 2011 October 24 to 2016 November 30. Among the 7938 EWs, the orbital periods of 7930 samples are included in VSX. The distribution of the orbital period for EWs observed by LAMOST is shown in Figure 1. Also displayed in the figure is the period distribution of all EWs in VSX, in which 139 EWs without orbital periods are not shown. Those spectroscopic data can be used during the photometric solutions and the large amount of data representing stellar spectra from the LAMOST survey provide important information for studying EWs. In the paper, EW binaries observed in the LAMOST survey are cataloged. Then, based on the distributions of those atmospheric parame ters and some statistical correlations, the physical properties and the formation and evolutionary states of EW binaries are discussed.
2. Catalog of EWs Observed by LAMOST
In recent LAMOST data releases, about 7938 EWs in the VSX catalog were observed from 2011 October 24 to 2016 November 30 and their spectral types were obtained. Among the 7938 EWs, the stellar atmospheric parameters of 5363 systems were determined when their spectra had sufficiently high signal to noise. The stellar atmospheric parameters including the effective temperature Teff, gravitational acceleration log(g), metallicity [Fe/H] and radial velocity (RV) Vr were automatically derived by the LAMOST stellar parameter pipeline when their spectra were of high quality (Wu et al. 2011b, 2014; Luo et al. 2015). Those stellar atmospheric parameters were determined based on the Universite de Lyon spectroscopic analysis software (ULySS) (Koleva et al. 2009; Wu et al. 2011a). ULySS fits complete observed spectra by using a model spectrum that is generated by an interpolator by using the ELODIE library as a reference (e.g., Prugniel & Soubiran 2001; Prugniel et al. 2007). When Teff < 8000 K, the standard deviations are 110 K, 0.19 dex and 0.11 dex for Teff, log(g) and [Fe/H] respectively. For RV Vr, the standard deviations are 4.91 km s−1 when Teff < 10 000 K (e.g., Gao et al. 2015).
The observations of 5363 EWs are cataloged in order of increasing VSX number. Some EWs were observed twice or more on different dates and we list all of the parameters. Values listed in Table 1 are the first 20 observations. The whole catalog is available through the internet (the electronic version of the catalog is at the website6) and it will be improved by adding new data obtained by LAMOST in the future. The table includes names of the binaries, their right ascension (R.A.) and declination (Dec.) coordinates, types of light variation and orbital periods. These parameters are from the VSX catalog. Entries shown in Column (6) are the distances (in arcsec) between the two positions determined by the coordinates given in VSX and by LAMOST. These distances were used to identify EWs from the LAMOST samples based on the criterion Dist< 2''. The observing dates are listed in Column (7), while the determined spectral types of EWs are shown in Column (8). The stellar atmospheric parameters Teff, log(g), [Fe/H] and Vr of the 5363 EWs are listed in Columns (9), (11), (13) and (15) respectively, and E1, E2, E3 and E4 in the table are their corresponding errors.
Table 1. Catalog of EWs Observed by LAMOST (the first 20 observations)
HU And | 003929.69 | +400459.8 | EW | 0.285789 | 0.360 | 2011–10–28 | G9 | 5158.97 | 246.09 | 4.431 | 0.352 | 0.126 | 0.229 | 0.73 | 18.92 |
IM And | 004646.80 | +393833.0 | EW | 0.270377 | 1.108 | 2014–12–12 | K3 | 4764.13 | 208.42 | 4.182 | 0.299 | −0.143 | 0.194 | −136.85 | 15.35 |
IM And | 004646.80 | +393833.0 | EW | 0.270377 | 1.108 | 2015–09–13 | K5 | 4977.45 | 73.29 | 4.692 | 0.105 | −0.029 | 0.068 | −157.15 | 5.28 |
LY And | 022152.54 | +383742.4 | EW | 0.34505 | 0.613 | 2013–11–12 | G2 | 5751.81 | 29.16 | 4.090 | 0.041 | −0.315 | 0.027 | 0.16 | 2.75 |
MT And | 022704.78 | +400328.5 | EW | 0.358781 | 0.767 | 2013–11–12 | G3 | 5676.33 | 204.28 | 3.931 | 0.293 | −0.136 | 0.190 | 14.41 | 15.32 |
MT And | 022704.78 | +400328.5 | EW | 0.358781 | 0.911 | 2013–10–14 | G3 | 5751.14 | 25.60 | 4.144 | 0.035 | 0.005 | 0.024 | −17.61 | 2.62 |
QX And | 015757.78 | +374822.5 | EW | 0.4121753 | 0.045 | 2014–11–10 | F5 | 6501.66 | 2.24 | 4.174 | 0.001 | −0.066 | 0.002 | 4.53 | 0.49 |
GK Aqr | 221956.93 | −007986.9 | EW | 0.3274145 | 0.344 | 2016–11–03 | K0 | 5302.35 | 7.27 | 4.274 | 0.005 | 0.384 | 0.006 | −17.35 | 1.81 |
GK Aqr | 221956.93 | −007986.9 | EW | 0.3274145 | 1.188 | 2012–10–04 | K1 | 5365.27 | 56.54 | 4.368 | 0.080 | 0.458 | 0.053 | −55.10 | 5.00 |
GM Aqr | 222157.94 | −028042.8 | EW | 0.3672853 | 0.491 | 2016–11–03 | G7 | 5636.36 | 21.72 | 4.296 | 0.030 | 0.153 | 0.021 | −66.66 | 2.33 |
GM Aqr | 222157.94 | −028042.8 | EW | 0.3672853 | 0.491 | 2012–10–04 | G7 | 5715.99 | 132.99 | 4.308 | 0.190 | 0.109 | 0.124 | 34.44 | 10.36 |
GS Aqr | 222733.63 | −005757.6 | EW | 0.374067 | 1.671 | 2015–11–09 | A5V | 7023.10 | 3.25 | 4.276 | 0.002 | −1.038 | 0.003 | −53.16 | 0.81 |
GS Aqr | 222733.63 | −005757.6 | EW | 0.374067 | 0.479 | 2016–11–03 | A7V | 7027.32 | 7.89 | 4.323 | 0.010 | −0.938 | 0.008 | −112.34 | 1.25 |
AH Aur | 062604.93 | +275956.4 | EW/KW | 0.494106 | 0.267 | 2012–02–01 | G3 | 6017.81 | 14.79 | 4.025 | 0.020 | 0.399 | 0.014 | 48.62 | 1.68 |
V0468 Aur | 045611.66 | +444638.9 | EW | 0.91278951 | 0.050 | 2012–02–09 | F5 | 6548.18 | 182.53 | 3.856 | 0.262 | −0.001 | 0.170 | 13.64 | 13.48 |
TU Boo | 140458.04 | +300001.5 | EW/KW | 0.3242868 | 0.144 | 2014–03–25 | G3 | 5828.78 | 9.41 | 4.295 | 0.012 | −0.027 | 0.009 | 7.13 | 1.32 |
TU Boo | 140458.04 | +300001.5 | EW/KW | 0.3242868 | 0.144 | 2016–05–18 | G3 | 5710.93 | 9.32 | 4.165 | 0.012 | −0.095 | 0.009 | −13.39 | 1.24 |
TZ Boo | 150809.13 | +395812.9 | EW/KW | 0.297162 | 0.081 | 2016–02–25 | G2 | 5597.28 | 6.21 | 4.179 | 0.008 | −0.746 | 0.006 | −59.65 | 0.92 |
AK Boo | 133839.06 | +241105.4 | EW/KE | 0.694030 | 0.436 | 2015–03–19 | G7 | 5526.82 | 95.45 | 4.065 | 0.136 | −0.326 | 0.089 | 45.21 | 7.77 |
AQ Boo | 134726.86 | +171824.7 | EW | 0.333139 | 0.936 | 2014–03–06 | G0 | 5680.80 | 2.64 | 4.037 | 0.002 | −0.466 | 0.002 | −52.13 | 0.59 |
The temperatures of most EWs are lower than 8000K and their standard deviations could be estimated reliably. However, both components of EWs are rapidly rotating and highly deformed stars that share a common envelope. Do their spectra have sufficient tracers necessary for unique determination of atmospheric parameters? There are 25 EWs that were observed five times or more. To check the reliability of stellar atmospheric parameters and to answer the question, we determined the mean values of their atmospheric parameters and derived the corresponding standard errors.
The results are shown in Table 2 where their names and orbital periods are listed in the first and second columns respectively. The observational times are shown in the third column, while the average atmospheric parameters and their standard errors are displayed in the other columns. As shown in Table 2, standard errors of the effective temperatures for all targets are lower than 110K. Apart from two targets, the standard errors of the gravitational acceleration log(g) for the other targets are lower than 0.19 dex. The standard errors of the metallicity for most EWtargets are lower than 0.11 dex. These resultsmay indicate that it does nomatter if we use single star spectra to calibrate peanut-shaped stars and demonstrate that the extracted parameters could reach the mentioned level of precision. Moreover, because those EWs were observed at different phases, the associated results also reveal that there are no obvious effects of phase on the derived atmospheric parameters across multiple observations of the same object within errors.
Table 2. Mean Atmospheric Parameters for 25 EWs Observed More than Four Times and Their Standard Errors
T-Lyr1-15705 | 0.298933 | 8 | 5473.44 | 68.40 | 4.340 | 0.101 | 0.117 | 0.070 |
LINEAR 6102187 | 0.324026 | 7 | 5479.31 | 94.55 | 4.234 | 0.153 | −0.047 | 0.041 |
CSS J074328.7+360725 | 0.391234 | 6 | 6158.67 | 67.58 | 4.157 | 0.072 | −0.084 | 0.123 |
CSS J222851.7+065242 | 0.370323 | 5 | 6687.61 | 109.41 | 4.064 | 0.104 | −0.322 | 0.089 |
CSS J111218.6+542629 | 0.317854 | 5 | 5421.22 | 61.99 | 4.339 | 0.072 | −0.042 | 0.031 |
CSS J093510.3+313745 | 0.295414 | 5 | 6056.15 | 72.54 | 4.089 | 0.090 | −0.572 | 0.017 |
CSS J090411.9+132908 | 0.273486 | 5 | 5135.15 | 33.33 | 4.165 | 0.090 | −0.404 | 0.058 |
CSS J082217.4+064452 | 0.340438 | 5 | 5780.39 | 89.51 | 4.070 | 0.192 | −0.236 | 0.093 |
CSS J073220.4+283612 | 0.274257 | 5 | 5330.87 | 47.72 | 4.332 | 0.113 | −0.189 | 0.041 |
CSS J070315.8+423814 | 0.368082 | 5 | 5767.00 | 62.65 | 4.173 | 0.080 | 0.099 | 0.041 |
CSS J025901.9+313046 | 1.0544407 | 5 | 6304.31 | 46.60 | 3.754 | 0.091 | 0.148 | 0.068 |
CSS J025613.4+311517 | 0.538159 | 5 | 6237.42 | 46.37 | 4.106 | 0.020 | −0.083 | 0.034 |
CSS J022913.6+042841 | 0.29825 | 5 | 5838.94 | 48.30 | 4.187 | 0.166 | −0.755 | 0.189 |
CSS J011822.4+080543 | 0.454696 | 5 | 6119.61 | 56.82 | 4.131 | 0.124 | −0.557 | 0.017 |
CSS J011310.1+370333 | 0.39251 | 5 | 6077.21 | 65.25 | 4.123 | 0.055 | −0.177 | 0.051 |
LINEAR 6446092 | 0.30679788 | 5 | 5484.59 | 43.30 | 4.381 | 0.196 | 0.172 | 0.068 |
NSVS 4831297 | 0.369811 | 5 | 5926.45 | 24.09 | 4.202 | 0.086 | 0.202 | 0.053 |
KID 06964796 | 0.399961 | 5 | 5939.73 | 27.60 | 4.237 | 0.044 | 0.133 | 0.014 |
KID 11084782 | 0.586555 | 5 | 8222.08 | 17.16 | 4.011 | 0.018 | −0.269 | 0.025 |
NSVS 4583537 | 0.40835410 | 5 | 6284.33 | 66.72 | 4.120 | 0.042 | −0.111 | 0.049 |
VSX J065147.6+592649 | 0.4217 | 5 | 5996.10 | 35.18 | 4.127 | 0.079 | 0.411 | 0.018 |
NY Boo | 0.32679 | 5 | 5779.52 | 30.98 | 4.115 | 0.055 | −0.076 | 0.027 |
NSVS 7209962 | 0.295931 | 5 | 5276.37 | 37.39 | 4.273 | 0.080 | 0.348 | 0.055 |
OP Leo | 0.391931 | 5 | 6104.86 | 51.49 | 4.129 | 0.061 | −0.385 | 0.053 |
ASAS J081149–0111.1 | 0.567286 | 5 | 6275.02 | 93.33 | 4.346 | 0.030 | 0.143 | 0.034 |
V0449 Gem | 0.270659 | 5 | 5045.36 | 42.53 | 4.321 | 0.049 | −0.048 | 0.026 |
V1022 Tau | 0.34717194 | 5 | 5882.69 | 52.00 | 4.193 | 0.049 | −0.255 | 0.045 |
The relative distribution (the percentage of the number to the whole sample) of orbital period for the 5363 EWs is displayed in Figure 2. For comparison, the relative period distribution of all EWs in VSX is also shown in the figure. It is found that they nearly overlap. This indicates that the 5363 EWs could be used to represent the properties of all EWs in the complete VSX catalog. As shown in Figures 1 and 2, the period distribution peaks are near 0.29 d (dashed line). This is shorter than that given by Paczyński et al. (2006) who obtain a peak near 0.37 d based on ASAS data (e.g., Pojmanski 1997; Pojmanski et al. 2005). This may be caused by the fact that ASAS is dedicated to the detection of variability in bright stars, but many faint short-period EWs were discovered by recent deep photometric surveys (e.g., Drake et al. 2009, 2014). Like cases analyzed by several investigators (e.g., Paczyński et al. 2006; Becker et al. 2011), it has a sharp cut-off at 0.2 d. A long tail exceeds 1 d and the tail actually extends to about 24 d.
Download figure:
Standard imageFor some LAMOST spectra of EW-type binaries, their signal to noise values are not high enough to determine the stellar atmospheric parameters. In those cases, only spectral types were identified. The spectral types of those EWs are also cataloged in order of increasing VSX number. The entries shown in Table 3 are the first 20 spectral types in the catalog. The whole table is available at the website7 via the internet. The catalog lists 3732 spectral types for 3055 EWs. Descriptions for those columns are the same as those in Table 1. For about 1691 EWs, only the spectral type was obtained by LAMOST. Both spectral types and stellar atmospheric parameters were determined for 5363 EWs. For the other ones, no results were obtained.
Table 3. Spectral Types Determined by LAMOST (the first 20 observations)
MS And | 022546.86 | +395845.5 | EW | 0.777900 | 0.559 | 2013–11–12 | K3 |
GS Aqr | 222733.63 | −005757.6 | EW | 0.374067 | 0.479 | 2012–10–29 | A5V |
MR Aur | 055133.68 | +310652.0 | EW | 0.690301 | 1.541 | 2011–11–10 | A2IV |
MR Aur | 055133.68 | +310652.0 | EW | 0.690301 | 1.541 | 2011–12–25 | A1V |
CK Boo | 143503.76 | +090649.4 | EW/RS | 0.355152 | 0.093 | 2016–04–24 | F0 |
GH Boo | 141451.51 | +273415.7 | EW | 0.65951 | 0.833 | 2015–01–15 | A8III |
GH Boo | 141451.51 | +273415.7 | EW | 0.65951 | 0.053 | 2016–05–15 | G7 |
GQ Boo | 145936.67 | +250244.9 | EW | 0.3846402 | 0.126 | 2012–06–05 | G8 |
GW Cnc | 084812.69 | +210713.8 | EW | 0.281413 | 0.053 | 2015–03–08 | G7 |
UZ CMi | 075051.76 | +033903.5 | EW/DW | 0.551361 | 0.180 | 2013–01–23 | F6 |
BB CMi | 075124.55 | +045439.2 | EW | 0.792866160 | 0.204 | 2013–01–23 | F0 |
SS Com | 124939.08 | +184211.9 | EW/KW | 0.412822 | 0.076 | 2016–05–19 | G7 |
EY Com | 131355.38 | +310454.1 | EW/KW | 0.2993278 | 0.715 | 2012–02–26 | K5 |
LP Com | 123305.52 | +270803.6 | EW | 0.33793358 | 0.107 | 2012–01–23 | K4 |
LP Com | 123305.52 | +270803.6 | EW | 0.33793358 | 0.107 | 2012–01–11 | K1 |
V2213 Cyg | 192857.89 | +430625.5 | EW | 0.350094 | 0.220 | 2014–09–13 | G7 |
V2284 Cyg | 192955.02 | +485500.1 | EW | 0.306994 | 0.014 | 2013–09–14 | G7 |
V2284 Cyg | 192955.02 | +485500.1 | EW | 0.306994 | 0.004 | 2015–10–01 | G7 |
IV Dra | 153623.26 | +531911.3 | EW | 0.268105 | 0.017 | 2013–05–03 | K5 |
IV Dra | 153623.26 | +531911.3 | EW | 0.268105 | 0.201 | 2012–06–17 | K3 |
3. Distributions of Stellar Atmospheric Parameters for EWs
As aforementioned, the stellar atmospheric parameters of 5363 systems were determined and their relative period distribution is the same as that of all EWs in VSX. Therefore, they could be used to investigate the properties of all EWs. During the analyses, when the EWs were observed two times or more, the stellar atmospheric parameters, effective temperature , gravitational acceleration log(g) and metallicity [Fe/H] were averaged and we used the mean values. For RV Vr, we did not average them because they were observed at different phases and vary with time.
The binary temperature distribution is shown in Figure 3 and the distribution has amain peak near 5700K (the solid line). This peak corresponds to the temperature of a G3-type main-sequence star with a stellar mass of about 0.97 (Cox 2000). This indicates that the majority of EWs are solar-type stars that have the protonproton (p-p) chain nuclear reaction occurring in their cores.
Download figure:
Standard imageFigure 3 also shows that there is a small peak near 6600K (the dashed line). This corresponds to the temperature of an F6-type main-sequence star with a stellar mass of about 1.35 . The transition from the first peak to the second small peak may reflect the central nuclear reaction changing from the p-p chain to the carbonnitrogen-oxygen (CNO) cycle. The distribution of gravitational acceleration log(g) is plotted in Figure 4. The distribution peaks near 4.16. It is apparent that the sample of EWsystems is homogeneous and most EWs are main-sequence binaries. This is in agreement with the idea that EWs are formed from detached main-sequence binaries via the combination of Case A mass transfer and angular momentum loss via magnetic braking (e.g., Qian et al. 2013a).
Download figure:
Standard imageThe metallicity ([Fe/H]) distribution is shown in Figure 5. EW-type binaries are usually composed of two solar-type stars. It is expected that their metallicities are similar to those detected among stars in the solar neighborhood (e.g., Rucinski et al. 2013). However, as visible in Figure 5, the metallicities of 80.6% of EWs are lower than that of the Sun, i.e., [Fe/H] < 0. For stars in the Galaxy, stellar metallicities are weakly correlated with their ages (e.g., Reid et al. 2007; Feltzing & Bensby 2009). The low metallicities indicate that most EWs are old stellar populations with longer ages. For a few percent of EWs, their metallicities are higher than 0.3 ([Fe/H] > 0.3). The possibility of unusually high metallicities may be through contamination by material from unseen degenerate objects (e.g., neutron stars or black holes) that are orbiting the binaries. Their progenitors were originally much more massive third stars in triple systems. Ten EWs that have the highest metallicities are shown in Table 4. They are a good source to search for potential degenerate objects (e.g., neutron stars or black holes) orbiting EWs.
Download figure:
Standard imageTable 4. Ten EWs with the Highest Metallicities
CSS_J080956.0+131054 | 0.316903 | K1 | 5692.04 | 4.491 | 0.677 | −50.76 |
VSX J001137.3+303145 | 0.41222 | F9 | 5719.4 | 4.088 | 0.637 | −66.27 |
CSS_J083051.6+185801 | 0.331662 | G5 | 5323.88 | 4.104 | 0.609 | 15.62 |
NSVS 2729390 | 0.347679 | K0 | 5490.45 | 4.36 | 0.586 | −63.81 |
ASAS J163229+0818.1 | 0.399559 | G8 | 5815.14 | 4.254 | 0.56 | −12.5 |
NSVS 4231740 | 0.40694612 | F9/G5 | 5809.96 | 4.085 | 0.557 | 35.28 |
V1047 Her | 0.32073733 | K1 | 5466.2 | 4.211 | 0.545 | −85.15 |
CSS_J032658.1+142940 | 0.385214 | G7 | 5650.16 | 4.336 | 0.524 | −2.23 |
CSS_J072417.0+224103 | 0.342338 | G8/K1 | 5497.9 | 4.233 | 0.519 | −37.3 |
CSS_J002629.5+445324 | 0.325968 | K1/K3 | 5043.48 | 4.398 | 0.514 | −0.99 |
The distribution of RV (Vr) for these EWs is displayed in Figure 6. 7382 RVs for 5363 EWs are used for constructing the figure. A peak is near Vr = −20 km s−1 and the distribution is symmetric. This may reveal that the V0 of most EWs is close to this value. The amplitudes of RV curves for EWs are about 150–300 km s−1 (e.g., Rucinski et al. 2001). Figure 6 reflects a statistically random sampling of RV curves for EWs. Sixteen EWs with RVs larger than 200 km s−1 are shown in Table 5. They may be observed near the maxima or minima of the RV curves of those EWs.
Download figure:
Standard imageTable 5. EWs Observed by LAMOST with RVs Larger than 200 km s−1
UY Hya | 0.7275 | A2V | 6697.05 | 4.233 | −1.834 | 359.43 |
CSS_J212703.2+100332 | 0.452204 | A5V | 7065.8 | 4.27 | −1.022 | −321.77 |
CSS_J212703.2+100332 | 0.452204 | A3V | 6817.47 | 4.248 | −1.039 | −316.4 |
CSS_J005447.7+284030 | 0.314908 | F0 | 6737.72 | 4.265 | −0.888 | −306.44 |
CSS_J032645.2+004931 | 0.705836 | F5 | 5826.79 | 4.062 | −1.405 | −304.7 |
CSS_J112812.6+045202 | 0.316715 | F5 | 5985.71 | 3.965 | −0.881 | 301.29 |
CSS_J214828.6+090336 | 1.42465 | F0 | 6611.71 | 4.365 | −1.17 | −285.31 |
CSS_J010448.7+373231 | 0.283694 | F0 | 6139.34 | 4.047 | −1.411 | −276.72 |
CSS_J014525.5+360334 | 0.270282 | G7 | 5342.15 | 4.101 | −0.579 | −264.58 |
CSS_J170410.6+274628 | 0.709314 | A9V | 6711.52 | 4.136 | −0.627 | −255.78 |
NSVS 7285749 | 0.323629 | F0 | 6438 | 4.322 | −1.018 | 242.96 |
CSS_J115356.5–022540 | 0.224256 | K2 | 5074.82 | 4.745 | −0.917 | 240.42 |
CSS_J072136.0+403327 | 0.340065 | F4 | 6714.6 | 4.409 | 0.467 | 230.7 |
NSVS 7285749 | 0.323629 | F0 | 6477.27 | 4.323 | −0.963 | 222.12 |
CSS_J012955.1+391130 | 0.317905 | F7 | 5932.42 | 4.1 | −0.52 | −216.98 |
LINEAR 14668373 | 0.224377 | G8 | 4989.28 | 4.014 | −1.591 | −212.1 |
CSS_J032034.5+203607 | 0.320948 | K5 | 5874.96 | 4.888 | 0.005 | 210.36 |
4. Statistical Correlations between Orbital Period and Stellar Atmospheric Parameters
The correlations between orbital period and effective temperature Teff, gravitational acceleration log(g) and metallicity [Fe/H] are shown in Figures 7–9, in which 55 EWs with orbital periods longer than 2 d are not displayed in the figures. Their orbital periods are from 2 d to 24 d. Six EWs are also not included in these figures because their orbital periods are unknown. Their atmospheric parameters are listed in Table 6. As shown in the three figures, the vast majority of EWs have periods in the range 0.2 < P < 0.6 d. The binary components in these short-period systems are usually main-sequence stars. However, there are some EW-type contact binaries with periods over 1 d. As plotted in Figure 8, the gravitational acceleration (log(g)) is weakly correlated with orbital period. The longer the orbital period is, the lower the gravitational acceleration will be. The lower log(g) of long-period systems indicates that the component stars have evolved from the zero-age main sequence.
Download figure:
Standard imageDownload figure:
Standard imageDownload figure:
Standard imageTable 6. LAMOST Observations of EWs without Orbital Periods
V0674 Per | 54.115 | 36.37417 | 2014–11–13 | K0 | 5046.24 | 4.307 | −0.162 | −39.99 |
V0726 Aur | 80.69046 | 29.11806 | 2014–11–03 | F9 | ||||
NSV 3633 | 113.47608 | 48.00353 | 2013–11–22 | F5 | 6327.91 | 4.174 | −0.428 | 1.75 |
NSV 3633 | 113.47608 | 48.00353 | 2015–01–31 | F5 | 6370.36 | 4.121 | −0.348 | 4.84 |
NSV 3633 | 113.47608 | 48.00353 | 2016–02–19 | F5 | 6353.80 | 4.128 | −0.362 | 14.10 |
NSV 5580 | 185.6305 | 25.82833 | 2012–01–11 | F7 | 6277.52 | 4.312 | 0.051 | 1.75 |
NSV 5580 | 185.6305 | 25.82833 | 2012–02–01 | F7 | 6230.28 | 4.341 | 0.033 | −17.33 |
NSV 5652 | 187.37508 | 29.51272 | 2012–01–11 | F7 | 6227.60 | 4.121 | 0.063 | −30.58 |
MG1 809127 | 240.96542 | 2.92944 | 2016–05–10 | A5V | ||||
Konkoly V14 | 81.62869 | 12.95734 | 2013–10–02 | F0 | 6857.67 | 3.474 | 0.396 | −16.07 |
SvkV34 | 85.75447 | 40.95046 | 2012–02–18 | K5 | 4520.01 | 4.382 | −0.001 | 23.93 |
Figure 7 shows that there is a good correlation between the orbital period and effective temperature Teff for short-period EWs (e.g., P < 0.6 d). This is more clearly seen in Figure 10 where only short-period EWs are shown. The red dashed line in Figure 10 refers to the peak value of the period distribution. The relation is similar to the period-color relation for EWs (e.g., Eggen 1961, 1967; Rucinski 1998; Terrell et al. 2012). Both main-sequence components in short-period EWs fill their critical Roche lobes and undergo CCE. It is expected that longerperiod systems should have higher-mass components with higher temperatures (e.g., Qian 2003). However, this relation shows a large scatter. This may be caused by the effect of the presence of third stars. Two examples of this case are 1SWASP J193127.17+465809.1 and 1SWASP J235935.22+362001.5 (e.g., Lohr et al. 2013). They are extremely short-period EWs with orbital periods 0.1976295 and 0.2016714d respectively. It is expected that they should be extremely cool binary systems. However, their spectral types determined by LAMOST are F0 with temperatures of 7027K and 7294K respectively. The possibility of a third body being present with spectral type of F0 can cause this difference. New spectroscopic and photometric data are very useful for studying these two interesting systems. Their positions in Figure 10 are shown as magenta solid triangles that greatly deviate from the general trend.
Download figure:
Standard imageThe other possible cause for the large scatter in the period-temperature relation is that the periods of some binaries are inaccurate. One example is CSS_J080814.1+184933. Its orbital period given in VSX is 0.493868 d. The green solid star in Figure 10 refers to its position which does not follow the general trend of the period-temperature relation. The phased light curve from using this period is shown in Figure 11. As we see in the figure, there are two primary minima and two secondary minima in one phased light curve. This indicates that the period is inaccurate. By using those new data, the period of the binary was revised to 0.246746 d. The phased light curve with the revised period is displayed in Figure 12 which is a typical EW-type light curve. The green solid circle in Figure 10 represents the updated position of the binary with the revised period. As shown in Figure 10, the period-temperature relation is tight, but this relation is not linear.
Download figure:
Standard imageDownload figure:
Standard imageRelations between the orbital period and log(g) and [Fe/H] for short-period EWs are shown in Figures 13 and 14 respectively. The positions of the three special EWs are also plotted in the two figures. Like what is depicted in Figure 10, the dashed lines represent the peak value of the period distribution. Figure 13 shows that log(g) is weakly correlated with orbital period. The relation for short-period systems (P < 0.29 d) is deeper than that for long-period ones (P > 0.29 d). As displayed in Figure 14, most of the EWs have lower metallicities (below the red solid line). Themetallicity is also weakly correlated with orbital period. Short-period EWs, with period shorter than 0.25 d, have metallicities below zero.
Download figure:
Standard imageDownload figure:
Standard image5. Discussion and Conclusions
Numerous EWs have been discovered through several large photometric surveys (e.g., CSS, the asteroid survey LINEAR, ASAS and NSVS). However, spectroscopic data are lacking for those EWs. Among 40 785 EWs listed in the VSX catalog, 7938 were observed in the LAMOST spectral survey from 2011 October 24 to 2016 November 30. We catalog those EWs and their spectral types are given. We also present stellar atmospheric parameters for 5363 of them. By analyzing 25 EWs observed five times or more by LAMOST, we show that the standard errors of the effective temperatures, gravitational acceleration and metallicity are usually lower than 110K, 0.19 dex and 0.11 dex, respectively. These results may indicate that the spectra of EWs have sufficient tracers necessary for unique determination of atmospheric parameters and the extracted parameters could reach the mentioned level of precision. However, to check the results obtained by LAMOST, a careful selection and a detailed spectroscopic investigation of some EWs observed by LAMOST are needed. We are observing some EWs spectroscopically and will determine their stellar atmospheric parameters and compare them with those obtained by LAMOST.
The derived effective temperatures as well as the spectral types by LAMOST are very useful for generating the photometric solutions of their light curves. The other atmospheric parameters provide us with valuable information to understand the formation and evolution ary state of EWs. We found that the peak of the period distribution is near 0.29 d, which is shorter than that given by previous investigators (e.g., Paczyński et al. 2006). This indicates that a large number of short-period faint EWs were discovered recently with deep photometric surveys. The distributions of effective temperature (T), gravitational acceleration (log(g)), metallicity ([Fe/H]) and RV are presented for observed EWs. There are two peaks in the temperature distribution that correspond to p-p chain and CNO nuclear reactions respectively in the cores of the components. The distribution of gravitational acceleration log(g) indicates that the components of most EWs are main-sequence stars, which is consistent with the idea that EWs are formed from detachedmain-sequence binaries via a combination of Case A mass transfer and angular momentum loss via magnetic braking (e.g., Qian et al. 2013b).
The detected metallicities of most sample stars (about 80.6%) are below zero. Since stellar metallicities are weakly correlated with their ages (e.g., Reid et al. 2007; Feltzing & Bensby 2009), this detection reveals that EW-type systems are old stellar populations. This supports the assumption that EWs need a long-term pre-contact evolution with timescales from a few hundred million to a few billion years. A few percent of EWs with unusually high metallicities may be contaminated by material from the evolutionary processes of unseen neutron stars or black holes in the systems. The progenitors of these unseen degenerate objects were originally much more massive third stars in triple systems. To date, neutron stars and black holes have usually been discovered in X-ray binaries through their X-ray radiation. They are formed through common envelope evolution and are influenced by their companion stars. If these unseen degenerate objects are confirmed, they will represent a new population of neutron stars and black holes (e.g., Qian et al. 2008; Ziolkowski 2010).
The correlations between orbital period and effective temperature, gravitational acceleration and metallicity are shown in previous sections. The scatters of those figures may be mainly caused by the presence of third bodies. EWs have the shortest period and lowest angular momentumamongmain-sequence binaries. It is assumed that they have a third body that plays an important role in their formation by removing angular momentum from the central binary (e.g., Qian et al. 2006, 2007, 2013a; Zhu et al. 2013b) For some systems, their orbital periods are inaccurate, which also causes scatters in those diagrams. It is shown that the relation between orbital period and effective temperature is tight but not linear.
Both gravitational acceleration and metallicity are weakly correlated with orbital period. The metallicities of all short-period EWs, with period shorter than 0.25 d, are below zero. These indicate that the physical properties of EWs mainly depend on their orbital periods. The formations and evolutionary states of EWs with different orbital periods may be quite different. This conclusion is supported by the relations between effective temperature (T) and gravitational acceleration log(g) and metallicity [Fe/H], which are shown in Figures 15 and 16 respectively. The dashed lines in the two figures refer to the peak of the temperature distribution at 5700K. It is found that both gravitational acceleration and metallicity are weakly correlated with effective temperature. Those extremely short-period EWs (P < 0.29 d; T < 5700K) usually have higher gravitational acceleration log(g) and lower metallicity [Fe/H]. They are main-sequence stars with little evolution and are older than their hotter cousins that have longer periods. This may suggest that they have a long timescale of pre-contact evolution and their formation and evolution are mainly driven by angular momentum loss via magnetic braking.
Download figure:
Standard imageDownload figure:
Standard imageAcknowledgements
This work is partly supported by the National Natural Science Foundation of China (No. 11325315). The Guo Shou Jing Telescope (the Large Sky Area Multi-Object Fiber Spectroscopic Telescope, LAMOST) is a National Major Scientific Project built by the Chinese Academy of Sciences. Funding for the project has been provided by the National Development and Reform Commission. LAMOST is operated and managed by National Astronomical Observatories, Chinese Academy of Sciences. Spectroscopic observations used in the paper were obtained with LAMOST from 2011 October 24 to 2016 November 30.
Footnotes
- 1
- 2
- 3
- 4
- 5
- 6
- 7