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<sup>22</sup>Ne Phase Separation as a Solution to the Ultramassive White Dwarf Cooling Anomaly

Simon Blouin, Jérôme Daligault, D. Saumon

2021The Astrophysical Journal Letters78 citationsDOIOpen Access PDF

Abstract

Abstract The precise astrometric measurements of the Gaia Data Release 2 have opened the door to detailed tests of the predictions of white dwarf cooling models. Significant discrepancies between theory and observations have been identified, the most striking affecting ultramassive white dwarfs. Cheng et al. found that a small fraction of white dwarfs on the so-called Q branch must experience an extra cooling delay of ∼8 Gyr not predicted by current models. 22 Ne phase separation in a crystallizing C/O white dwarf can lead to a distillation process that efficiently transports 22 Ne toward its center, thereby releasing a considerable amount of gravitational energy. Using state-of-the-art Monte Carlo simulations, we show that this mechanism can largely resolve the ultramassive cooling anomaly if the delayed population consists of white dwarfs with moderately above-average 22 Ne abundances. We also argue that 22 Ne phase separation can account for the smaller cooling delay currently missing for models of white dwarfs with more standard compositions.

Topics & Concepts

White dwarfPhysicsAnomaly (physics)AstrophysicsWhite (mutation)PopulationPhase (matter)StarsChemistryCondensed matter physicsGeneDemographyQuantum mechanicsSociologyBiochemistryStellar, planetary, and galactic studiesGamma-ray bursts and supernovaeAstro and Planetary Science
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