Seven new triply eclipsing triple star systems

Rappaport, S. A.; Borkovits, T.; Mitnyan, T.; Gagliano, R.; Eisner, N.; Jacobs, T.; Tokovinin, A.; Powell, B.; Kostov, V.; Omohundro, M.; Kristiansen, M. H.; Jayaraman, R.; Terentev, I.; Schwengeler, H. M.; LaCourse, D.; Garai, Z.; Pribulla, T.; Maxted, P. F. L.; Bíró, I. B.; Csányi, I.; Pál, A.; Vanderburg, A.

doi:10.1051/0004-6361/202449273

A&A

2024

DOI: 10.1051/0004-6361/202449273

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Seven new triply eclipsing triple star systems

S. A. Rappaport,

T. Borkovits,

T. Mitnyan

et al.

Abstract: We have identified nearly a hundred close triply eclipsing hierarchical triple star systems from data taken with the space telescope TESS. These systems are noteworthy in that we can potentially determine their dynamical and astrophysical parameters with a high precision. In the present paper, we report the comprehensive study of seven new compact triply eclipsing triple star systems taken from this larger sample: TICs 133771812, 176713425, 185615681, 287756035, 321978218, 323486857, and 650024463. Most of th… Show more

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Cited by 3 publications

References 76 publications

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Spectroscopy of eclipsing compact hierarchical triples

Moharana,

Hełminiak,

Marcadon

et al. 2024

A&A

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Eclipsing compact hierarchical triples (CHTs) are systems in which a tertiary star orbits an eclipsing binary (EB) in an orbit of fewer than 1000 days. In a CHT, all three stars exist in a space that is less than 5 AU in radius. A low-mass CHT is an interesting case through which we can understand the formation of multiple stars and planets at such small scales. In this study, we combine spectroscopy and photometry to estimate the orbital, stellar, and atmospheric parameters of stars in a sample of CHTs. Using the complete set of parameters, we aim to constrain the metallicity and age of the systems. We used time-series spectroscopy to obtain radial velocities (RVs) and disentangled spectra. Using RV modelling, EB light curve modelling, and spectral analysis, we estimated the metallicities and temperatures. Using isochrone fitting, we constrained the ages of the system. We then combined observations of masses, outer eccentricities ($e_2$), orbital periods, and age estimates of the systems from the literature. We compared the distributions of $e_2$, and the tertiary mass ratio, $q_3 = M_3/(M_1+M_2)$, for three different metallicity ranges and two age ranges. We have estimated the masses, radii, temperatures, metallicities, and ages of 12 stars in four CHTs. The CHT CD-32 6459 shows signs of von Zeipel-Lidov-Kozai oscillations, while CD-62 1257 can evolve to form a triple common envelope. The rest of the CHTs are old and have an M-dwarf tertiary. We find that the $q_3$ distribution for CHTs with sub-solar metallicity has a uniform distribution but the systems with solar and above-solar metallicity peak between 0.5 and 1. When dividing them according to their ages, we find the $q_3$ of old systems to be around 0.5. The eccentricity, $e_2$, favours a value of around 0.3 irrespective of metallicity or age. The distributions of $q_3$ and $e_2$ resemble the distributions of the mass ratio and eccentricity of close field binaries.

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Spectroscopy of eclipsing compact hierarchical triples

Moharana,

Hełminiak,

Marcadon

et al. 2024

A&A

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TIC 290061484: A Triply Eclipsing Triple System with the Shortest Known Outer Period of 24.5 Days

Kostov,

Rappaport,

Borkovits

et al. 2024

ApJ

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We have discovered a triply eclipsing triple-star system, TIC 290061484, with the shortest known outer period, P out, of only 24.5 days. This “eclipses” the previous record set by λ Tauri at 33.02 days, which held for 68 yr. The inner binary, with an orbital period of P in = 1.8 days, produces primary and secondary eclipses and exhibits prominent eclipse timing variations with the same periodicity as the outer orbit. The tertiary star eclipses, and is eclipsed by, the inner binary with pronounced asymmetric profiles. The inclinations of both orbits evolve on observable timescales such that the third-body eclipses exhibit dramatic depth variations in TESS data. A photodynamical model provides a complete solution for all orbital and physical parameters of the triple system, showing that the three stars have masses of 6.85, 6.11, and 7.90 M ⊙, radii near those corresponding to the main sequence, and T eff in the range of 21,000–23,700 K. Remarkably, the model shows that the triple is in fact a subsystem of a hierarchical 2+1+1 quadruple with a distant fourth star. The outermost star has a period of ∼3200 days and a mass comparable to the stars in the inner triple. In ∼20 Myr, all three components of the triple subsystem will merge, undergo a Type II supernova explosion, and leave a single remnant neutron star. At the time of writing, TIC 290061484 is the most compact triple system and one of the tighter known compact triples (i.e., P out/P in = 13.7).

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Precision Timing of Eclipsing Binaries from TESS Full Frame Images: Method and Performance

Marcadon,

Prša

2024

ApJ

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Several hundreds of thousands of eclipsing binaries (EBs) are expected to be detected in the Transiting Exoplanet Survey Satellite (TESS) full frame images (FFIs). This represents a significant increase in the number of EBs available for eclipse timing variation studies. In this paper, we investigate the feasibility of performing precise eclipse timing of TESS EBs using the FFIs. To this end, we developed a fast, automated method and applied it to a sample of ∼100 EBs selected from the Villanova TESS EB catalog. Our timing analysis resulted in the detection of 10 new triple candidates with outer periods shorter than ∼1300 days. For five of them, we were able to constrain the outer orbit by analyzing independently the short-cadence (SC) and FFI data and to derive the minimum mass of the third body with a precision better than 4% for SC and 11% for FFI data. We then compared the results obtained from the two data sets and found that using the FFI data leads to (1) a degradation of both the accuracy and precision of the tertiary mass determination for the tightest EBs and (2) an overall underestimation of the third component’s mass. However, we stress that our main conclusions on the nature of the detected signals do not depend on which data set is used. This confirms the great potential of TESS FFIs, which will allow us to search for rare objects such as substellar circumbinary companions and compact triple stellar systems.

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Seven new triply eclipsing triple star systems

Cited by 3 publications

References 76 publications

Spectroscopy of eclipsing compact hierarchical triples

Spectroscopy of eclipsing compact hierarchical triples

TIC 290061484: A Triply Eclipsing Triple System with the Shortest Known Outer Period of 24.5 Days

Precision Timing of Eclipsing Binaries from TESS Full Frame Images: Method and Performance

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