Dwarf carbon (dC) stars are low-mass, main-sequence stars that exhibit spectra analogous
to carbon-rich giants found along the asymptotic giant branch. An almost half a century
old hypothesis postulates that the peculiar atmospheric chemistry of dC stars is owed to
mass transfer from an evolved companion. Speci cally, while the former primary ascended
the asymptotic giant branch, triple- -processed material was dredged to the surface before
the stellar wind liberated the carbon-enhanced outer layers. The liberated material is then
transferred to the main-sequence companion, polluting its atmosphere, and forming a dC star,
while the original primary becomes a white dwarf.
In this thesis, I present the results of a decade-long spectroscopic survey of 37 dC stars to
test this binary evolution hypothesis. Using MCMC simulations to analyse the radial-velocity
variations of all 37 dC stars in this sample, it has been possible to show that the population is
consistent with a 100 per cent binary fraction and are thus likely the product of mass transfer.
Furthermore, the orbital parameters of nine dC stars are reported for the rst time, increasing
the number of known dC binaries by 220 per cent. Interestingly, eight of these newly constrained
dC binaries exhibit emission features in their optical spectrum. Moreover, the orbital periods of
these emission-line dC stars are all shorter than 12 d, implying that these stars have evolved
through a common envelope. Thus, the discovery of eight short-orbital period dC stars indicates
that low-mass, metal-weak or metal-poor stars can accrete substantial material before entering
the common-envelope phase.
Finally, a kinematical study of 1200 candidate dC stars is presented, with the analysis indicating
that as much as 70 per cent of the population may possess Galactic orbits that are
inconsistent with thin disc membership. This result, therefore, suggests that dC stars are
generally old and likely metal-poor.