A highly magnetized and rapidly rotating white dwarf as small as the Moon

Caiazzo, Ilaria; Burdge, Kevin B.; Fuller, James; Heyl, Jeremy; Kulkarni, S. R.; Prince, Thomas A.; Richer, Harvey B.; Schwab, Josiah; Andreoni, Igor; Bellm, Eric C.; Drake, A. J.; Duev, Dmitry A.; Graham, M. J.; Hélou, G.; Mahabal, A.; Masci, Frank J.; Smith, Roger M.; Soumagnac, Maayane T.

doi:10.1038/s41586-021-03615-y

Cited by 86 publications

(85 citation statements)

References 78 publications

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“…The downward triangles mark when 10 % of the mass is solid while the upward triangles mark when 90% of the mass is solid. The large star shows ZTF J190132.9+145808.7 (Caiazzo et al 2021) and the small star shows WD J183202.83+085636.24 (Pshirkov et al 2020).…”

Section: Resultsmentioning

confidence: 99%

“…In addition to controlling when the latent heat of the phase transition is released, once material becomes solid, the gravitational potential energy stored in neutron-rich isotopes can no longer be released through their preferential transport towards the center. Realizing a scenario where a massive WD is meta-stable and will exceed its effective Chandrasekhar mass due to sedimentation, such as is speculated by Caiazzo et al (2021) for ZTF J190132.9+145808.7, requires rapid and near-complete sedimentation.…”

Section: Resultsmentioning

confidence: 99%

“…As an example, we apply our models to ZTF J190132.9+145808.7 (Caiazzo et al 2021) 5, the best fit parameters place ZTF J190132.9+145808.7 in a region where neutrinos produced through the Urca process have accelerated the cooling of the WD.…”

Section: Discussionmentioning

confidence: 99%

“…As our sample of nearby WDs becomes increasing complete, thanks in large part to Gaia (Gaia Collaboration et al 2018;Gentile Fusillo et al 2019), a significant number of white dwarfs with masses 1.3 M are being revealed and better described. These include longstudied objects like GD 50 (Bergeron et al 1991;Gagné et al 2018) and RE J0317-853 (Barstow et al 1995;Ferrario et al 1997;Külebi et al 2010) as well more recently characterized objects like WD J183202.83+085636.24 (Pshirkov et al 2020) and ZTF J190132.9+145808.7 (Caiazzo et al 2021). In their analysis of the 100 pc sample from the Montreal White Dwarf Database, Kilic et al (2021) identify 25 WDs with masses > 1.3 M (assuming H atmospheres and C/O cores).…”

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confidence: 99%

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Cooling Models for the Most Massive White Dwarfs

Schwab

2021

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We present a set of ultramassive white dwarf models, focused on masses above 1.3 M . Given the uncertainties about the formation and compositions of such objects, we construct parameterized model sequences, guided by evolutionary calculations including both single star and double white dwarf merger formation channels. We demonstrate that the cooling of objects with central densities in excess of 10 9 g cm −3 is dominated by neutrino cooling via the Urca process in the first ≈ 100 Myr after formation. Our models indicate that the recently discovered ultramassive white dwarf ZTF J190132.9+145808.7 is likely to have experienced this Urca-dominated cooling regime. We also show that the high densities imply that diffusion is unlikely to significantly alter the core compositions of these objects before they crystallize.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Cooling Models for the Most Massive White Dwarfs

Schwab

2021

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“…These stars play a key role in ★ The cooling sequences are publicly available for download at http://evolgroup.fcaglp.unlp.edu.ar/TRACKS/tracks.html † E-mail: maria.camisassa@colorado.edu our understanding of type Ia Supernova explosions, the occurrence of physical processes in the asymptotic giant-branch (AGB) phase, the existence of high-field magnetic white dwarfs, and the occurrence of double white dwarf mergers (Dunlap & Clemens 2015;Reindl et al 2020). The observation of ultra-massive white dwarfs has been reported in several studies in the literature (Mukadam et al 2004;Nitta et al 2016;Gianninas et al 2011;Kleinman et al 2013;Bours et al 2015;Kepler et al 2016;Curd et al 2017;Kilic et al 2021;Hollands et al 2020;Caiazzo et al 2021;Miller et al 2021).…”

Section: Introductionmentioning

confidence: 99%

The evolution of ultra-massive carbon oxygen white dwarfs

Camisassa,

Althaus,

Koester

et al. 2022

Preprint

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Ultra-massive white dwarfs (M WD 1.05 M ⊙ ) are considered powerful tools to study type Ia supernovae explosions, merger events, the occurrence of physical processes in the Super Asymptotic Giant Branch (SAGB) phase, and the existence of high magnetic fields. Traditionally, ultra-massive white dwarfs are expected to harbour oxygen-neon (ONe) cores. However, new observations and recent theoretical studies suggest that the progenitors of some ultramassive white dwarfs can avoid carbon burning, leading to the formation of ultra-massive white dwarfs harbouring carbon-oxygen (CO) cores. Here we present a set of ultra-massive white dwarf evolutionary sequences with CO cores for a wide range of metallicity and masses. We take into account the energy released by latent heat and phase separation during the crystallization process and by 22 Ne sedimentation. Realistic chemical profiles resulting from the full computation of progenitor evolution are considered. We compare our CO ultra-massive white dwarf models with ONe models. We conclude that CO ultra-massive white dwarfs evolve significantly slower than their ONe counterparts mainly for three reasons: their larger thermal content, the effect of crystallization, and the effect of 22 Ne sedimentation. We also provide colors in several photometric bands on the basis of new model atmospheres. These CO ultramassive white dwarf models, together with the ONe ultra-massive white dwarf models, provide an appropriate theoretical framework to study the ultra-massive white dwarf population in our Galaxy.

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Equation of state and surface thermal emission of magnetized white dwarfs

et al. 2022

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The observation and theoretical study of massive magnetized white dwarfs is one of the most important topics in the field of astronomy. This paper aims to obtain a coupled magneto-thermal evolution model of magnetized white dwarfs (B-WDs). As a fiducial model, we choose a non-magnetized WD with a baryonic mass M 0 = 1.37 M ⊙ (M ⊙ is the solar mass) for comparison with the magnetized cases. Firstly, we give an overview of the WD cooling, then study the equation of the state of a B-WD. We find that the WD mass increases with magnetic field strength B, while its radius decreases with B, and the minimum of B required to reach the Chandrasecka limit is about 3.2 × 10 14 G. Finally, by introducing the magnetic-to-thermal conversion coefficient ξ, and taking the temperature effect on the stellar radius into consideration, we calculate the luminosities of thermal photons L ph and surface effective temperature, T eff due to Ohmic dissipation for B-WDs. According to our calculations, magnetic field decay can definitely maintain a long-term thermal evolution for massive B-WDs. This study will be useful for the study of internal thermal evolution and internal stability of B-WDs in the future.

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A highly magnetized and rapidly rotating white dwarf as small as the Moon

Cited by 86 publications

References 78 publications

Cooling Models for the Most Massive White Dwarfs

Cooling Models for the Most Massive White Dwarfs

The evolution of ultra-massive carbon oxygen white dwarfs

Equation of state and surface thermal emission of magnetized white dwarfs

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