Abstract
White dwarfs represent the last stage of evolution of stars with mass less than about eight times that of the Sun and, like other stars, are often found in binaries1,2. If the orbital period of the binary is short enough, energy losses from gravitational-wave radiation can shrink the orbit until the two white dwarfs come into contact and merge3. Depending on the component masses, the merger can lead to a supernova of type Ia or result in a massive white dwarf4. In the latter case, the white dwarf remnant is expected to be highly magnetized5,6 because of the strong magnetic dynamo that should arise during the merger, and be rapidly spinning from the conservation of the orbital angular momentum7. Here we report observations of a white dwarf, ZTF J190132.9+145808.7, that exhibits these properties, but to an extreme: a rotation period of 6.94minutes, a magnetic field ranging between 600megagauss and 900megagauss over its surface, and a stellar radius of [Formula: see text] kilometres, only slightly larger than the radius of the Moon. Such a small radius implies that the star's mass is close to the maximum white dwarf mass, or Chandrasekhar mass. ZTF J190132.9+145808.7 is likely to be cooling through the Urca processes (neutrino emission from electron capture on sodium) because of the high densities reached in its core.
Highlights
Division of Physics, Mathematics and Astronomy, California Institute of Technology, Pasadena, Department of Physics and Astronomy, University of British Columbia, Vancouver, BC, V6T1Z1, Canada
J190132.9+145808.7, which presents all these properties, but to an extreme: a rotation period of 6.94 minutes, one of the shortest measured for an isolated white dwarf9, 10, a magnetic field ranging between 600 MG and 900 MG over its surface, one of the highest fields ever detected on a white dwarf[11 ], and a stellar radius of 1810 km, slightly larger than the radius of the Moon
We find that most of the spectral features are well characterised by a field strength of about million Gauss (MG, red horizontal line), one of the highest fields ever detected on a white dwarf[11]
Summary
This indicates that in some regions of the white dwarf’s surface the magnetic field is as low as 600 MG. Even in the case of formation due to a white-dwarf merger, compressional heating due to rapid accretion is expected to ignite off-center carbon burning.
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