A New Algol-type Binary with an Accretion disk
Abstract
We present a comprehensive photometric and spectroscopic analysis of the Algol-type binary Gaia DR3 1892576067672499328. We identified the system as a spectroscopic binary based on medium-resolution LAMOST spectra. Combined with TESS photometry, we determine an orbital period of \( P = 2.47757 (1) \) days, a low mass ratio of \( q = 0.098 0.002 \), and an orbital inclination of \( i = 46.934+2.613-1.11 \) degrees. The orbit is consistent with being circular (\( e = 0 \)). The binary comprises a \( M1 = 1.817 +0.106-0.202 \,M \), \( R1 = 1.265+0.121-0.160\,R \) A-type primary and a Roche-lobe-filling secondary of \( M2 = 0.179 +0.011-0.020 \,M \), \( R2 = 1.994 +0.041-0.077 \,R \). The double-peak Hα emission line indicates the possible existence of a Keplerian accretion disc. We established a simple standard accretion disc model and modeled the geometric and dynamical properties of the accretion disc. The obtained outer disc radius Rout ≈ 3.36 0.43\,R is consistent with the values inferred from the emission velocity of Hα. Systemic velocity variations observed over time suggest the possible presence of a tertiary companion, with a minimum mass of M3 > 0.369 0.024 \,M. Given the low mass ratio, the secondary may evolve into a proto-helium white dwarf, forming an EL CVn-type system in the future. This system offers valuable insights into accretion dynamics and the formation of binaries.
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