A Gravitational Redshift Measurement of the White Dwarf Mass-Radius Relation

Chandra, Vedant; Hwang, Hsiang-Chih; Zakamska, Nadia L.; Cheng, Sihao

doi:10.48550/arxiv.2007.14517

Cited by 2 publications

(2 citation statements)

References 39 publications

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“…We compare the spectrum with Koester (2010) models assuming a WD mass of 0.8 M and logg = 8.5, scaled to the distance of AR Sco. The choice of logg = 8.5 for this mass WD is consistent with the recent study by Chandra et al (2020). Different choices for the mass or gravity are possible as these are not well constrained.…”

Section: The Trough Spectrumsupporting

confidence: 81%

Peeking Between the Pulses: The Far-UV Spectrum of the Previously Unseen White Dwarf in AR Scorpii

Garnavich,

Littlefield,

Lyutikov

et al. 2020

Preprint

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The compact object in the interacting binary AR Sco has widely been presumed to be a rapidly rotating, magnetized white dwarf (WD), but it has never been detected directly. Isolating its spectrum has proven difficult because the spin-down of the WD generates pulsed synchrotron radiation that far outshines the WD's photosphere. As a result, a previous study of AR Sco was unable to detect the WD in the averaged far-ultraviolet spectrum from a Hubble Space Telescope (HST) observation. In an effort to unveil the WD's spectrum, we reanalyze these HST observations by calculating the average spectrum in the troughs between synchrotron pulses. We identify weak spectral features from the previously unseen WD and estimate its surface temperature to be 11500±500 K. Additionally, during the synchrotron pulses, we detect broad Lyman-α absorption consistent with hot WD spectral models. We infer the presence of a pair of hotspots, with temperatures between 23000 K and 28000 K, near the magnetic poles of the WD. As the WD is not expected to be accreting from its companion, we describe two possible mechanisms for heating the magnetic poles. The Lyman-α absorption of the hotspots appears relatively undistorted by Zeeman splitting, constraining the WD's field strength to be 100 MG, but the data are insufficient to search for the subtle Zeeman splits expected at lower field strengths.

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Section: The Trough Spectrumsupporting

confidence: 81%

Peeking Between the Pulses: The Far-UV Spectrum of the Previously Unseen White Dwarf in AR Scorpii

Garnavich,

Littlefield,

Lyutikov

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…Nonetheless, at the moderate magnetic field strengths found at these white dwarfs, the overall spectral energy distribution of a star should not be significantly affected and, given an accurate distance measurement, T eff and log g can be reliably determined from broad-band photometry alone (e.g. Koester et al 1979) when also making use of the wellestablished mass-radius relation of white dwarfs (Panei et al 2000;Tremblay et al 2017;Parsons et al 2017;Joyce et al 2018;Chandra et al 2020 adopted this method to estimate atmospheric parameters for GD356, SDSS J1252−0234, and SDSS J1219+4715 using the Gaia photometry and astrometry, and non-magnetic white dwarf model atmospheres. In the temperature range of these three stars, non-magnetic white dwarfs with hydrogen-rich atmospheres develop convection zones.…”

Section: White Dwarf Parametersmentioning

confidence: 99%

Single magnetic white dwarfs with Balmer emission lines: A small class with consistent physical characteristics as possible signposts for close-in planetary companions

Gaensicke,

Rodriguez-Gil,

Fusillo

et al. 2020

Preprint

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We report the identification of SDSS J121929.45+471522.8 as the third apparently isolated magnetic (B 18.5 ± 1.0 MG) white dwarf exhibiting Zeeman-split Balmer emission lines. The star shows coherent variability at optical wavelengths with an amplitude of 0.03 mag and a period of 15.26 h, which we interpret as the spin period of the white dwarf. Modelling the spectral energy distribution and Gaia parallax, we derive a white dwarf temperature of 7500 ± 148 K, a mass of 0.649 ± 0.022 M , and a cooling age of 1.5 ± 0.1 Gyr, as well as an upper limit on the temperature of a sub-stellar or giant planet companion of 250 K. The physical properties of this white dwarf match very closely those of the other two magnetic white dwarfs showing Balmer emission lines: GD356 and SDSS J125230.93−023417.7. We argue that, considering the growing evidence for planets and planetesimals on close orbits around white dwarfs, the unipolar inductor model provides a plausible scenario to explain the characteristics of this small class of stars. The tight clustering of the three stars in cooling age suggests a common mechanism switching the unipolar inductor on and off. Whereas Lorentz drift naturally limits the lifetime of the inductor phase, the relatively late onset of the line emission along the white dwarf cooling sequence remains unexplained.

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A Gravitational Redshift Measurement of the White Dwarf Mass-Radius Relation

Cited by 2 publications

References 39 publications

Peeking Between the Pulses: The Far-UV Spectrum of the Previously Unseen White Dwarf in AR Scorpii

Peeking Between the Pulses: The Far-UV Spectrum of the Previously Unseen White Dwarf in AR Scorpii

Single magnetic white dwarfs with Balmer emission lines: A small class with consistent physical characteristics as possible signposts for close-in planetary companions

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