Photometric and Spectroscopic analysis of four contact binaries

TL;DR

This study provides detailed photometric and spectroscopic analysis of four W UMa contact binaries, revealing their period variations, physical parameters, chromospheric activity, and evolutionary status, using observational data and modeling tools.

Contribution

It offers new insights into the period changes, activity, and evolutionary state of four contact binary systems through combined photometric, spectroscopic, and modeling analyses.

Findings

J0158 and J0305 show period increase; J1022 shows period decrease; KW Psc's period remains unchanged.

Spectral analysis indicates chromospheric activity via emission lines.

Secondary components are more evolved than primaries, away from ZAMS.

Abstract

We present the photometric and spectroscopic analysis of four W UMa binaries J015829.5+260333 (hereinafter as J0158), J030505.1+293443 (hereinafter as J0305), J102211.7+310022 (hereinafter as J1022) and KW Psc. The VRcIc band photometric observations are carried out with the 1.3-m Devasthal Fast Optical Telescope. For low resolution spectroscopy, we used 2-m Himalayan Chandra Telescope as well as the archival data from 4-m LAMOST survey. The systems J0158 and J0305 show a period increase rate of 5.26(+/-1.72)x10^-7 days/yr and 1.78(+/-1.52)x10^-6 days/yr, respectively. The period of J1022 is found to be decreasing with a rate of 4.22(+/-1.67)x10^-6 days/yr. The period analysis of KW Psc displays no change in its period. PHOEBE package is used for the light curve modeling and basic parameters are evaluated with the help of GAIA parallax. The asymmetry of light curves is explained with the assumption of cool spots at specific positions on one of the components of the system. On the basis of temperatures, mass ratios, fill-out factors and periods, the system J1022 is identified as W-subtype systems while the others show some mixed properties. To probe the chromospheric activities in these W UMa binaries, their spectra are compared with the known inactive stars spectra. The comparison shows emission in H\alpha, H\beta and CaII. To understand the evolutionary status of these systems, the components are drawn in mass-radius and mass-luminosity planes with other well characterized binary systems. The secondary components of all the systems are away from ZAMS which indicates that secondary is more evolved than the primary component.