Medium-resolution spectroscopic study of the intermediate-mass pre-main sequence binary θ1 Ori E
Abstract
θ1 Ori E is a very young and relatively massive pre-main sequence (PMS) spectroscopic and eclipsing binary with nearly identical components. We analyze \'Echelle spectra of the system obtained over fifteen years and report 91 radial velocities measured from cross-correlating the observations with a suitable synthetic spectrum. The spectra of individual binary components are indistinguishable from each other, with a composite spectral type around G4 III. The projected equatorial velocity is estimated to be v i = 32 3~km~s-1, consistent with rotational synchronization. We find that the circular orbit has P orb = 9.89522 0.00003~d, K1 = 83.36 0.29~km~s-1, K2 = 84.57 0.28~km~s-1, and asini = 32.840.08\ R. The mass ratio is q = 0.9856 0.0047, indicating nearly identical but significantly different masses. The systemic velocity of the binary, γ = 29.7 0.2~km~s-1, is similar to that of other Trapezium members. Using Spitzer light curves and our results, we derive M1 = 2.7550.043\ M, M2 = 2.7200.043\ M, R1=6.260.31R and R2=6.250.30R. Together with our estimate of the effective temperature, T eff=5150200\ K, a bolometric luminosity of 28.84.6\ L is derived for each component. Compared to evolutionary models of PMS stars, the binary age turns out to be less than or equal to 105 years. Its components are probably the most massive stars known with masses determined with precision better than 2 percent, with both being PMS stars.
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