Abstract

<i>Context. <i/>We present a catalog of 857 white dwarf (WD)-M binaries from the sixth data release (DR6) of the Sloan Digital Sky Survey (SDSS), most of which were previously identified. For 636 of them, we complete a spectral analysis and derive the basic parameters of their stellar constituents and their distances from Earth.<i>Aims. <i/>We attempt to measure fundamental parameters of these systems by completing spectral analyses. We propose to test models typically applied in fitting procedures and constrain likely and appropriate evolutionary scenarios for the systems.<i>Methods. <i/>We use a minimization technique to decompose each combined spectrum and derive independent parameter estimates for its components. The possibility of alignment by chance is demoted to statistical insignificance, hence, we use physical interaction of the binary constituents as input parameter. Additionally, we check the corresponding photometric data from the SDSS to find optically resolved systems.<i>Results. <i/>Forty-one of the stellar duets in our spectroscopic sample are optically resolved in their respective SDSS images. For these systems, we also derive a minimum true spatial separation and a lower limit to their orbital periods, typically which are some 10<sup>4<sup/> yr. Spectra of 167 stellar duets show significant hydrogen emission and in most cases no additional He i or He ii features. We also find that 20 of the 636 WDs are fitted to be DOs, with 16 measured to have around 40 000 K. Furthermore, we identify 70 very low-mass objects (VLMOs), which are secondaries of masses smaller than about 0.1 , to be candidate substellar companions.<i>Conclusions. <i/>Although various selection effects may play a role, the fraction 6.4% of WD-M star binaries with orbital separations of around 500 AU is a criterion for evolutionary models of stellar binary systems. Of the 167 spectra with hydrogen emission, 8 had already been found to be post-common envelope binaries (PCEBs) and 4 are systems with strong irradiation processes on the M dwarf. The remaining 155 Balmer-emitting binaries probably harbor an active M dwarf (dM), corresponding to a fraction of 24.4%. The excess of cool DOs is most likely due to additional WDs in the DB-DO range, for which no detailed fitting was completed. The trend of the M stars being closer to Earth than the WD component is probably due to an underestimation of the theoretical M star radii.

Highlights

  • The study of white dwarf (WD)-M star systems is an important research area because they constitute a common final stage object of stellar evolution, a WD, and the most frequent type of star: the M component

  • Heller et al.: WD-M star binaries from the sloan digital sky survey atmosphere fitting for the WD primaries and spectral typing based on the M-dwarf template spectra of Beuermann et al (1998) and Bochanski et al (2007) for the secondaries

  • Another earlier study of WDs in wide binaries was completed by Greenstein (1986), and we found three of his 56 systems to be in our master sample, one of a quality too low for a reliable analysis

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Summary

Introduction

The study of white dwarf (WD)-M star systems is an important research area because they constitute a common final stage object of stellar evolution, a WD, and the most frequent type of star: the M component. 2. Silvestri et al (2007) presented a study of 1253 detached close binary systems from the SDSS data release 5 (DR5) (Adelman-McCarthy et al 2007), most of them which consisted of WD primaries and M dwarf companions. R. Heller et al.: WD-M star binaries from the sloan digital sky survey atmosphere fitting for the WD primaries and spectral typing based on the M-dwarf template spectra of Beuermann et al (1998) and Bochanski et al (2007) for the secondaries. We used the J2000 coordinates calculated by VizieR to relate stars with each other Another earlier study of WDs in wide binaries was completed by Greenstein (1986), and we found three of his 56 systems to be in our master sample, one of a quality too low for a reliable analysis. We find 41 optically resolved binaries with wide-separated constituents of long orbital periods (Sect. 5.3)

Observations
Premises
Models
Mathematical treatment
Optically resolved binaries
Results
White dwarfs showing He lines
Spectra with emission
Very low-mass objects
Discussion

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