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

Brown, Thomas M.; Sweigart, A. V.; Lanz, T.; Landsman, W. B.; Hubený, I.

doi:10.1086/323862

Cited by 196 publications

(430 citation statements)

References 60 publications

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“…Stars that undergo an early hot flash are located on the blue end of the canonical EHB of the H-R diagram (e.g., see Fig. 9 in Brown et al 2001). The second type is called late hot flash, for which the helium flash occurs on a WD cooling curve (after the primary star experiences a huge mass loss on the RGB).…”

Section: Resultsmentioning

confidence: 99%

“…The second type is called late hot flash, for which the helium flash occurs on a WD cooling curve (after the primary star experiences a huge mass loss on the RGB). In this type, the helium flash can change the chemical composition of its envelope by enhancing the helium and carbon abundance through helium-flash mixing (Iben 1976;Sweigart 1997;Brown et al 2001). Therefore, the late hot flashers have significantly higher effective temperatures on the HB, and they are fainter than the canonical EHB stars in the CMD.…”

Section: Resultsmentioning

confidence: 99%

“…The late-hot-flash model has been used to explain the existence of blue-hook stars found in several massive GCs (Whitney et al 1998;D'Cruz et al 2000;Brown et al 2001). In our calculations, however, we did not consider the helium-flash mixing process.…”

Section: Resultsmentioning

confidence: 99%

“…3.1, which correspond to a higher effective temperature than the canonical EHB stars. Brown et al (2001) have suggested that these stars undergo a late hot helium flash while descending along one of the WD cooling curves. The helium and carbon abundance in the envelope of these stars are enhanced by the helium flash mixing, which is not considered in our model calculations (see discussion in Sect.…”

Section: Model Comparison With Observations For Gc Ngc 2808mentioning

confidence: 99%

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Effects of tidally enhanced stellar wind on the horizontal branch morphology of globular clusters

Lei

Chen

Zhang

et al. 2013

A&A

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Context. Metallicity is the first parameter to influence the horizontal branch (HB) morphology of globular clusters (GCs). It has been found, however, that some other parameters may also play an important role in affecting the morphology. While the nature of these important parameters remains unclear, they are believed to be likely correlated with wind mass-loss of red giants, since this mass loss determines their subsequent locations on the HB. Unfortunately, the mass loss during the red giant stages of the stellar evolution is poorly understood at present. Aims. The stellar winds of red giants may be tidally enhanced by companion stars if they are in binary systems. We investigate the evolutionary consequences of red giants in binaries by including tidally enhanced stellar winds, and examine the effects on the HB morphology of GCs. Methods. We used Eggleton's stellar evolution code to study the binary evolution. The tidally enhanced stellar-wind model of Tout & Eggleton is incorporated into this code, where the tidal enhancement parameter, B w , has various values (e.g., 10 000 and 500) to examine the dependency of the final results on this parameter. A Monte Carlo simulation was performed to generate a group of binary systems. The position of each primary star on the HB in the Hertzsprung-Russell diagram in this sample is obtained through interpolations among the constructed HB evolutionary tracks. Finally, a synthetic HB in the color-magnitude diagram is obtained by transforming the effective temperature and luminosity of each primary star on the HB into B − V colors and absolute magnitude. Results. We find that red, blue, and extreme horizontal branch stars are all produced under the effects of tidally enhanced stellar wind without any additional assumptions on the mass-loss dispersion. Furthermore, the horizontal branch morphology is found to be insensitive to the tidal enhancement parameter, B w . We compare our theoretical results with the observed horizontal branch morphology of globular cluster NGC 2808, and find that the basic morphology of the horizontal branch can be well reproduced. The number of blue horizontal branch stars in our calculations, however, is lower than that of NGC 2808.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Model Comparison With Observations For Gc Ngc 2808mentioning

confidence: 99%

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Effects of tidally enhanced stellar wind on the horizontal branch morphology of globular clusters

Lei

Chen

Zhang

et al. 2013

A&A

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“…In fact, even beyond the EHB proper there may still be "life" on the HB phase: as recently discussed by several authors, the RGB progenitors of HB stars may (somehow) lose so much mass prior to arriving on the ZAHB that they may miss the helium "flash" at the RGB tip altogether, but still ignite helium during the white dwarf cooling curve (e.g., [8,13]). Such "late flashers" are predicted to be even hotter than EHB stars, and have quite anomalous surface abundances compared to EHB stars (see, e.g., [60,61,49]).…”

Section: Introductionmentioning

confidence: 98%

Horizontal Branch Stars and the Ultraviolet Universe

Catelan

2009

Astrophysics and Space Science Proceedings

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Summary. Extremely hot horizontal branch (HB) stars and their progeny are widely considered to be responsible for the "ultraviolet upturn" (or UVX) phenomenon observed in elliptical galaxies and the bulges of spirals. Yet, the precise evolutionary channels that lead to the production of these stars remain the source of much debate. In this review, we discuss two key physical ingredients that are required in order for reliable quantitative models of the UV output of stellar populations to be computed, namely, the mass loss rates of red giant branch stars and the helium enrichment "law" at high metallicities. In particular, the recent evidence pointing towards a strong enhancement in the abundances of the α-elements in the Galactic bulge (compared to the disk), and also the available indications of a similar overabundance in (massive) elliptical galaxies, strongly suggest that the helium abundance Y may be higher in ellipticals and bulges than it is in spiral disks by an amount that may reach up to 0.15 at [Fe/H] ∼ +0.5. If so, this would strongly favor the production of hot HB stars at high metallicity in galactic spheroids. We also discuss the existence of mass loss recipes beyond the commonly adopted Reimers "law" that are not only more consistent with the available empirical data, but also much more favorable to the production of extended HB stars at high metallicity. Finally, we discuss new empirical evidence that suggests that different evolutionary channels may be responsible for the production of EHB stars in the field and in clusters.

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2015

Pulsating Stars

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

Cited by 196 publications

References 60 publications

Effects of tidally enhanced stellar wind on the horizontal branch morphology of globular clusters

Effects of tidally enhanced stellar wind on the horizontal branch morphology of globular clusters

Horizontal Branch Stars and the Ultraviolet Universe

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