The Rapid Rotation of the Strongly Magnetic Ultramassive White Dwarf EGGR 156

Williams, Kurtis A.; Hermes, J. J.; Vanderbosch, Zachary P.

doi:10.3847/1538-3881/ac8543

Cited by 14 publications

(5 citation statements)

References 56 publications

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“…In addition to the agreement of the rotational and cooling ages, the full proof of the present scenario would arise from the further agreement of the model spin-down rate with corresponding observational measurement (see, e.g., the case of 4U 0142+61 in Rueda et al 2013). For the magnetic dipole braking mechanism (see Equation ( 15)), the spin-down rate is given by ´-P 3.3 10 sin 17 2  s s −1 (see also Williams et al 2022). This spin-down rate is too low to be detected, e.g., two orders of magnitude lower than the one of the pulsating WD G 117-B15A, »…”

Section: Rotational Evolution Of J2211+1136supporting

confidence: 60%

The Double White Dwarf Merger Progenitors of SDSS J2211+1136 and ZTF J1901+1458

Sousa

Coelho

Araújo

et al. 2022

ApJ

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Double white dwarf (DWD) mergers are possibly the leading formation channel of massive, rapidly rotating, high-field magnetic white dwarfs (HFMWDs). However, a direct link connecting a DWD merger to any observed HFMWD is still missing. We here show that the HFMWDs SDSS J221141.80+113604.4 (hereafter J2211+1136) and ZTF J190132.9+145808.7 (hereafter J1901+1458) might be DWD merger products. J2211+1136 is a 1.27 M ⊙ white dwarf (WD) with a rotation period of 70.32 s and a surface magnetic field of 15 MG. J1901+1458 is a 1.327–1.365 M ⊙ WD with a rotation period of 416.20 s, and a surface magnetic field in the range 600–900 MG. With the assumption of single-star evolution and the currently measured WD masses and surface temperatures, the cooling ages of J2211+1136 and J1901+1458 are, respectively, 2.61–2.85 Gyr and 10–100 Myr. We hypothesize that these WDs are DWD merger products and compute the evolution of the postmerged configuration formed by a central WD surrounded by a disk. We show that the postmerger system evolves through three phases depending on whether accretion, mass ejection (propeller), or magnetic braking dominates the torque onto the central WD. We calculate the time the WD spends in each of these phases and obtain the accretion rate and disk mass for which the WD rotational age, i.e., the total time elapsed since the merger to the instant where the WD central remnant reaches the current measured rotation period, agrees with the estimated WD cooling age. We infer the mass values of the primary and secondary WD components of the DWD merger that lead to a postmerger evolution consistent with the observations.

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Section: Rotational Evolution Of J2211+1136supporting

confidence: 60%

The Double White Dwarf Merger Progenitors of SDSS J2211+1136 and ZTF J1901+1458

Sousa

Coelho

Araújo

et al. 2022

ApJ

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“…Kilic et al (2021) argued that assuming a hydrogen atmosphere, an inclination, and an offset dipole geometry, the lines could not be reasonably reproduced. We found a good fit Another interesting case is the star SDSS J225726.05 +075541.6 featured in Williams et al (2022). They stated that the observed Balmer lines are significantly weaker than predicted by the atmospheric models, which could be explained if the star were in an unresolved binary system, but the allowable parameter space for such a binary is minuscule.…”

Section: Particular Starssupporting

confidence: 51%

Catalog of Magnetic White Dwarfs with Hydrogen Dominated Atmospheres

Amorim

Külebi

Jordan

et al. 2023

ApJ

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White dwarfs are excellent research laboratories as they reach temperatures, pressures, and magnetic fields that are unattainable on Earth. To better understand how these three physical parameters interact with each other and with other stellar features, we determined the magnetic field strength for a total of 804 hydrogen-rich white dwarfs (WDs) of which 287 are not in the literature. We fitted the spectra observed with the Sloan Digital Sky Survey using atmospheric models that consider the Zeeman effect due to the magnetic field at each point in the stellar disk. Comparing magnetic and nonmagnetic WDs, the literature already shows that the magnetic ones have on average higher mass than the nonmagnetic. In addition to that, magnetic fields are more common in cooler WDs than in hotter WDs. In consonance, we found that those with higher magnetic field strengths tend to have higher masses, and lower temperatures, for which models indicate the crystallization process has already started. This reinforces the hypothesis that the field is being generated and/or amplified in the cooling process of the white dwarf. Our sample constitutes the largest number of white dwarfs with determined magnetic fields to date.

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“…Conversely, complete positron confinement requires a relatively strong ( 10 6 G) and/or morphologically complex magnetic field (e.g., Table 2 from Hristov et al 2021). Strong magnetic fields can be produced in the merger of two white dwarfs (e.g., Williams et al 2022) but it is unclear how the magnetic field strength and morphology will be affected by the explosion (e.g., Remming & Khokhlov 2014). Alternatively, particle streaming instabilities can generate magnetic fields (e.g., Gupta et al 2021), but no simulations have assessed if nebular-phase SNe Ia ejecta meet the required instability criteria.…”

Section: Resultsmentioning

confidence: 99%

Serendipitous Nebular-phase JWST Imaging of SN Ia 2021aefx: Testing the Confinement of 56-Co Decay Energy

Chen¹,

Tucker²,

Hoyer³

et al. 2023

Preprint

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We present new 0.3 − 21 µm photometry of SN 2021aefx in the spiral galaxy NGC 1566 at +357 days after B-band maximum, including the first detection of any SN Ia at > 15 µm. These observations follow earlier JWST observations of SN 2021aefx at +255 days after the time of maximum brightness, allowing us to probe the temporal evolution of the emission properties. We measure the fraction of flux emerging at different wavelengths and its temporal evolution. Additionally, the integrated 0.3 − 14 µm decay rate of ∆m 0.3−14 = 1.35 ± 0.05 mag/100 days is higher than the decline rate from the radioactive decay of 56 Co of ∼ 1.2 mag/100 days. The most plausible explanation for this discrepancy is that flux is shifting to > 14 µm, and future JWST observations of SNe Ia will be able to directly test this

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The Rapid Rotation of the Strongly Magnetic Ultramassive White Dwarf EGGR 156

Cited by 14 publications

References 56 publications

The Double White Dwarf Merger Progenitors of SDSS J2211+1136 and ZTF J1901+1458

The Double White Dwarf Merger Progenitors of SDSS J2211+1136 and ZTF J1901+1458

Catalog of Magnetic White Dwarfs with Hydrogen Dominated Atmospheres

Serendipitous Nebular-phase JWST Imaging of SN Ia 2021aefx: Testing the Confinement of 56-Co Decay Energy

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