* Astronomy

Blobrana · L

RE: NSVS 14256825

Blobrana · L

Title: On the dynamical stability of the proposed planetary system orbiting NSVS 14256825
Authors: Robert A. Wittenmyer, Jonathan Horner, Jonathan Marshall

We present a detailed dynamical analysis of the orbital stability of the two circumbinary planets recently proposed to orbit the evolved eclipsing binary star system NSVS 14256825. As is the case for other recently proposed circumbinary planetary systems detected through the timing of mutual eclipses between the central binary stars, the proposed planets do not stand up to dynamical scrutiny. The proposed orbits for the two planets are extremely unstable on timescales of less than a thousand years, regardless of the mutual inclination between the planetary orbits. For the scenario where the planetary orbits are coplanar, a small region of moderate stability was observed, featuring orbits that were somewhat protected from destabilisation by the influence of mutual 2:1 mean-motion resonance between the orbits of the planets. Even in this stable region, however, the systems tested typically only survived on timescales of order 1 million years, far shorter than the age of the system.
Our results suggest that, if there are planets in the NSVS 14256825 system, they must move on orbits dramatically different to those proposed in the discovery work. More observations are clearly critically required in order to constrain the nature of the suggested orbital bodies.

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Blobrana · L

Title: A photometric and spectroscopic study of NSVS 14256825: the second sdOB+dM eclipsing binary
Authors: L. A. Almeida, F. Jablonski, J. Tello, C. V. Rodrigues

We present an analysis of UBVR_{C}I_{C}JH photometry and phase-resolved optical spectroscopy of NSVS 14256825, an HW Vir type binary. The members of this class consist of a hot subdwarf and a main-sequence low-mass star in a close orbit (P_{orb} ~ 0.1 d). Using the primary-eclipse timings, we refine the ephemeris for the system, which has an orbital period of 0.11037 d. From the spectroscopic data analysis, we derive the effective temperature, T_1 = 40000 ±500 K, the surface gravity, \log g_1 = 5.50 ±0.05, and the helium abundance, n(He)/n(H)=0.003 ±0.001, for the hot component. Simultaneously modelling the photometric and spectroscopic data using the Wilson-Devinney code, we obtain the geometrical and physical parameters of NSVS 14256825. Using the fitted orbital inclination and mass ratio (i = 82\fdg5 ±0\fdg3 and q = M_2/M_1 = 0.260 ±0.012, respectively), the components of the system have M_1 = 0.419 ±0.070 solar masses, R_1 = 0.188 ±0.010 solar radii, M_2 = 0.109 ±0.023 solar masses, and R_2 = 0.162 ±0.008 solar radii. From its spectral characteristics, the hot star is classified as an sdOB star.

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