Configuration of the ξ Tau system constrained by multi-technique observations

Abstract

ξ Tau is one of the most compact multiple stellar systems, which is sufficiently close (67 pc) to be constrained by all kinds of observations. To better constrain its current configuration, we utilized new observational data: (i) photometry from TESS and astrometry from WDS, and (ii) our own photometry from the MOST spacecraft and spectroscopy from the CTIO observatory. [...] Given the hierarchical architecture of ξ Tau, ((Aa+Ab)+B)+C, we detected the orbital evolution on all time scales. Oscillations of periods P occur on the shortest, orbital time scales (P1, P2); the variation of eccentricity e1 is from 0 to 0.008, and of e2 from 0.202 to 0.207, respectively. Oscillations of projected i, Ω are coupled, and occur on the secular time scale of about 7000 d. The inclination i1 of the inner, eclipsing pair (Aa+Ab) changes from 86.1 to 87.1, which is clearly manifested in eclipse depths. There is also a long-term trend due to the outer orbit (P3 18900\, d), with a perihelion passage (a `bump') of component C, which is manifested in radial velocities. The mutual inclinations between the three orbital planes, \,0.5 and 71, are very different. Long-term stability is ensured by suppressing Kozai oscillations due to the fast precession rate ω2. The best model requires tidal dissipation in the inner binary (with the time lag of 100\, s) and five components, where component C is a binary (Ca+Cb). Although the masses of the three components (2.27, 2.15, 3.78\,M) are now constrained to within 1%, the suspected binary (Ca+Cb), offset by 600\, mas, should be better characterized. A key question remains whether this bright stellar system contains additional dwarf or exoplanetary components with low masses. Continuing monitoring of ξ Tau is highly desirable.