Rd. Jeffries et Ir. Stevens, WIND-ACCRETION INDUCED RAPID ROTATION AND A NEW CLASS OF ACTIVE STAR, Monthly Notices of the Royal Astronomical Society, 279(1), 1996, pp. 180-190
A physical model is presented to explain the occurrence of wide binary
systems discovered at EUV wavelengths, such as 2RE J0044+093, which c
onsist of a hot white dwarf and an ultra-rapidly rotating K-dwarf. It
is difficult to explain the rapid rotation of the K-dwarf as a consequ
ence of either youth or close binarity because of the length of the ev
olutionary and cooling time-scales for the white dwarf and the lack of
any radial velocity variations. It is proposed that accretion of the
slow, massive wind from the asymptotic giant branch (AGB) progenitor o
f the white dwarf, by the low-mass secondary in a detached configurati
on, can transfer sufficient angular momentum to produce these systems.
For a range of AGB masses, and wind velocities of 10-20 km s(-1), it
is found that secondary spin up to periods of less than 10 h can take
place for final orbital separations of up to 100 au. If the secondarie
s are wind-accretion induced, rapidly rotating stars (or WIRRing stars
), they could show signs of chemical enrichment in carbon and s-proces
s elements, such as barium, that were present in the AGB wind. The det
ection of such overabundances would lend firm support for this hypothe
sis and provide an evolutionary link between WIRRing stars and Barium
giants. It is also suggested that the rapidly rotating, late-type cent
ral stars of planetary nebulae, such as Abel 35, are the progenitors o
f WIRRing stars, seen shortly after the mass accretion phase.