Flash Mixing on the White Dwarf Cooling Curve: Understanding Hot Horizontal Branch Anomalies in NGC 2808

We present a UV CMD spanning the hot horizontal branch (HB), blue straggler, and white dwarf populations of the globular cluster NGC 2808. These data were obtained with the Space Telescope Imaging Spectrograph (STIS). Although previous optical CMDs of NGC 2808 show a high temperature gap within the hot HB population, no such gap is evident in our UV CMD. Instead, we find a population of hot subluminous HB stars, an anomaly only previously reported for the globular cluster omega Cen. Our modeling indicates that the location of these subluminous stars in the UV CMD, as well as the high temperature gap along the HB in optical CMDs, can be explained if these stars underwent a late He-core flash while descending the white dwarf cooling curve. We show that the convection zone produced by such a late He flash will penetrate into the H envelope, thereby mixing H into the hot He-burning interior, where it is rapidly consumed. This phenomenon is analogous to the "born again" scenario for producing H-deficient stars following a late He-shell flash. The flash mixing of the envelope greatly enhances the envelope He and C abundances, and leads, in turn, to a discontinuous increase in the HB effective temperatures at the transition between canonical and flash-mixed stars. We argue that the hot HB gap is associated with this theoretically predicted dichotomy in the HB properties. Moreover, the changes in the emergent spectral energy distribution caused by these abundance changes are primarily responsible for explaining the hot subluminous HB stars. Although further evidence is needed to confirm that a late He-core flash can account for the subluminous HB stars and the hot HB gap, we demonstrate that an understanding of these stars requires the use of appropriate theoretical models for their evolution, atmospheres, and spectra.
26 pages, Latex. 17 figures. Uses corrected version of emulateapj.sty and apjfonts.sty (included). Accepted for publication in ApJ. T.M. Brown currently at STScI