2020
DOI: 10.1093/mnras/staa2167
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Fundamental effective temperature measurements for eclipsing binary stars – I. Development of the method and application to AI Phoenicis

Abstract: Stars with accurate and precise effective temperature (Teff) measurements are needed to test stellar atmosphere models and calibrate empirical methods to determine Teff. There are few standard stars currently available to calibrate temperature indicators for dwarf stars. Gaia parallaxes now make it possible, in principle, to measure Teff for many dwarf stars in eclipsing binaries. We aim to develop a method that uses high-precision measurements of detached eclipsing binary stars, Gaia parallaxes and multi-wave… Show more

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Cited by 25 publications
(18 citation statements)
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“…Moreover, a promising further direction is the inclusion of the modelling of the net stellar energy distribution (SED), which enables the determination of temperatures for each stellar component with precision close to or better than 1%. Recently, for example, Miller et al [266] have developed a sophisticated method for the SED modelling of totally eclipsing detached EBs, and demonstrated that, under ideal circumstances, their method is able to reach the required accuracy in the two stars' temperatures. Their method, however, cannot be adopted directly to multiple stellar systems, although it does indicate a promising direction.…”
Section: Discussionmentioning
confidence: 99%
“…Moreover, a promising further direction is the inclusion of the modelling of the net stellar energy distribution (SED), which enables the determination of temperatures for each stellar component with precision close to or better than 1%. Recently, for example, Miller et al [266] have developed a sophisticated method for the SED modelling of totally eclipsing detached EBs, and demonstrated that, under ideal circumstances, their method is able to reach the required accuracy in the two stars' temperatures. Their method, however, cannot be adopted directly to multiple stellar systems, although it does indicate a promising direction.…”
Section: Discussionmentioning
confidence: 99%
“…Moreover, a further fundamental question in such an accurate analysis is the precision of the effective temperatures of the binary members. Recently Miller et al (2020) have developed a new method to determine the temperatures of eclipsing binary stars with a precision better than 1%, via a careful analysis of the system's net spectral energy distribution (SED) while taking into account the components' flux ratio, as 'quasi observables', that can be measured from high quality multi-band occultation lightcurves of some totally eclipsing binaries. Unfortunately, however, due to the significant light contributions of the third stellar components in our systems, as well as the lack of flat-bottomed binary eclipses and the strongly varying profiles of the third-body eclipses, this latter rigorous method for precise SED analysis cannot be applied directly to our triples.…”
Section: Spectro-photodynamical Modelingmentioning
confidence: 99%
“…Second, proximity effects (reflection effect, ellipsoidal effect, gravity darkening) are more complex to model and can make it impossible to determine radii to 0.1% precision (e.g., [265]). A benchmark EB must also have high-quality T eff measurements (a recent approach by Miller et al [346] is promising) and spectroscopic chemical abundances [347].…”
Section: Future Workmentioning
confidence: 99%