The dawn of a new era for dustless HdC stars with<i>Gaia</i>eDR3

Tisserand, Patrick; Crawford, Courtney L.; Clayton, Geoffrey C.; Ruiter, Ashley J.; Karambelkar, Viraj; Bessell, M. S.; Seitenzahl, Ivo R.; Kasliwal, Mansi M.; Soon, J.; Travouillon, Tony

doi:10.1051/0004-6361/202142916

Cited by 10 publications

(14 citation statements)

References 116 publications

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“…In addition, dLHdC stars have lower absolute magnitudes than RCB stars with the same color and shorter pulsation periods (Tisserand et al 2022), which as our models show, hints that dLHdC stars may have lower masses. If true, then dLHdC stars are ideal for studying pulsations in HdC stars, not just because they do not show dust ejection episodes but also because nonadiabatic effects are less important.…”

Section: Discussionsupporting

confidence: 65%

“…Furthermore, the inferred number of galactic RCB stars (e.g., Tisserand et al 2020) is broadly consistent with that expected from the He WD-CO WD merger rate (e.g., Ruiter et al 2009;Karakas et al 2015), whereas the final flash stars spend too little time in the RCB phase to explain the number of known RCB stars (Clayton et al 2006). It has been suggested that dLHdC stars are similarly formed through mergers but with different mass ratios (e.g., Karambelkar et al 2022;Tisserand et al 2022).…”

Section: Introductionsupporting

confidence: 74%

“…Similar periods are found in the infrared light curves of five RCB stars (Karambelkar et al 2021). Only 13 out of 32 dLHdC stars have detectable variability from ASAS-SN (Tisserand et al 2022), with lower peak-to-peak photometric amplitudes of 0.05-0.15 mag, shorter periods of 10-40 days, and lower radial velocity amplitudes (Lawson & Cottrell 1997;Tisserand et al 2023).…”

Section: Introductionsupporting

confidence: 60%

“…Because of its smaller radius, its pulsation periods (and period corresponding to n max ) are also shorter. This points to a smaller mass for dLHdC stars, which have shorter pulsation periods as well as lower absolute magnitudes than RCB stars (≈10-40 days; Tisserand et al 2022).…”

Section: Discussionmentioning

confidence: 98%

“…While RCB stars normally have M V between −3 and −5 (e.g., Alcock et al 2001;Tisserand et al 2009), they often show large optical photometric declines (sometimes reaching 9 mag) lasting years, caused by dust ejection episodes. Closely related to RCB stars are dustless hydrogen-deficient carbon (dLHdC) stars, which show RCB-like spectra but do not show dust ejection episodes (e.g., Warner 1967;Tisserand et al 2022). In this work, we do not distinguish between RCB and dLHdC stars but use HdC as an umbrella term encasing both.…”

Section: Introductionmentioning

confidence: 99%

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The Asteroseismological Richness of RCB and dLHdC Stars

Wong,

Bildsten

2024

ApJ

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RCB stars are L ≈ 104 L ⊙ solar-mass objects that can exhibit large periods of extinction from dust ejection episodes. Many exhibit semi-regular pulsations in the range of 30–50 days with semi-amplitudes of 0.05–0.3 mag. Space-based photometry has discovered that solar-like oscillations are ubiquitous in hydrogen-dominated stars that have substantial outer convective envelopes, so we explore the hypothesis that the pulsations in RCB stars and the closely related dustless hydrogen-deficient carbon (dLHdC) stars, which have large convective outer envelopes of nearly pure helium, have a similar origin. Through stellar modeling and pulsation calculations, we find that the observed periods and amplitudes of these pulsations follows the well-measured phenomenology of their H-rich brethren. In particular, we show that the observed modes are likely of angular orders l = 0, 1, and 2 and predominantly of an acoustic nature (i.e., p-modes with low radial order). The modes with largest amplitude are near the acoustic cutoff frequency appropriately rescaled to the helium-dominated envelope, and the observed amplitudes are consistent with that seen in high-luminosity (L > 103 L ⊙) H-rich giants. We also find that for T eff ≳ 5400 K, an hydrogen-deficient carbon stellar model exhibits a radiative layer between two outer convective zones, creating a g-mode cavity that supports much longer period (≈100 days) oscillations. Our initial work was focused primarily on the adiabatic modes, but we expect that subsequent space-based observations of these targets (e.g., with TESS or Plato) are likely to lead to a larger set of detected frequencies that would allow for a deeper study of the interiors of these rare stars.

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Section: Discussionsupporting

confidence: 65%

Section: Introductionsupporting

confidence: 74%

Section: Introductionsupporting

confidence: 60%

Section: Discussionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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The Asteroseismological Richness of RCB and dLHdC Stars

Wong,

Bildsten

2024

ApJ

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The discovery space of ELT-ANDES. Stars and stellar populations

Roederer,

Alvarado-Gómez,

Allende Prieto

et al. 2024

Exp Astron

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R Coronae Borealis and dustless hydrogen-deficient carbon stars likely have different oxygen isotope ratios

Karambelkar

Kasliwal

Tisserand

et al. 2022

A&A

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Context. R Coronae Borealis (RCB) and dustless Hydrogen-deficient Carbon (dLHdC) stars are believed to be remnants of low mass white dwarf mergers. These supergiant stars have peculiar hydrogen-deficient carbon-rich chemistries and stark overabundances of 18 O. RCB stars undergo dust formation episodes resulting in large-amplitude photometric variations that are not seen in dLHdC stars. Recently, the sample of known dLHdC stars in the Milky Way has more than quintupled with the discovery of 27 new dLHdC stars. Aims. It has been suggested that dLHdC stars have lower 16 O/ 18 O than RCB stars. We aim to compare the 16 O/ 18 O ratios for a large sample of dLHdC and RCB stars to examine this claim. Methods. We present medium resolution (R≈ 3000) near-infrared spectra of 20 newly discovered dLHdC stars. We also present medium resolution (R≈ 3000 − 8000) K-band spectra for 49 RCB stars. Due to the several free parameters and assumptions in our fitting strategy, we provide wide range estimates on the 16 O/ 18 O ratios of seven dLHdC and 33 RCB stars that show 12 C 16 O and 12 C 18 O absorption bands, and present the largest sample of such 16 O/ 18 O wide-range values for dLHdC and RCB stars to date. Results. We find that six of the seven dLHdC stars have 16 O/ 18 O < 0.5, while 28 of the 33 RCB stars have 16 O/ 18 O > 1. We also confirm that unlike RCB stars, dLHdC stars do not show strong blueshifted (> 200 km s −1 ) He i 10833 Å absorption, suggesting the absence of strong, dust-driven winds around them. Conclusions. Although we only can place wide range estimates on the 16 O/ 18 O and these are more uncertain in cool RCBs, our medium resolution spectra suggest that most dLHdC stars have lower 16 O/ 18 O than most RCB stars. This confirms one of the first, long-suspected spectroscopic differences between RCB and dLHdC stars. The different oxygen isotope ratios rule out the existing picture that RCB stars represent an evolved stage of dLHdC stars. Instead, we suggest that whether the white dwarf merger remnant is a dLHdC or RCB star depends on the mass ratios, masses and compositions of the merging white dwarfs. Future high resolution spectroscopic observations will help confirm and more precisely quantify the difference between the oxygen isotope ratios of the two classes.

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The dawn of a new era for dustless HdC stars withGaiaeDR3

Cited by 10 publications

References 116 publications

The Asteroseismological Richness of RCB and dLHdC Stars

The Asteroseismological Richness of RCB and dLHdC Stars

The discovery space of ELT-ANDES. Stars and stellar populations

R Coronae Borealis and dustless hydrogen-deficient carbon stars likely have different oxygen isotope ratios

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