Dr Simone Scaringi simone.scaringi@durham.ac.uk
Associate Professor
Magnetically gated accretion in an accreting ‘non-magnetic’ white dwarf
Scaringi, S.; Maccarone, T.J.; D’Angelo, C.; Knigge, C.; Groot, P.J.
Authors
T.J. Maccarone
C. D’Angelo
C. Knigge
P.J. Groot
Abstract
White dwarfs are often found in binary systems with orbital periods ranging from tens of minutes to hours in which they can accrete gas from their companion stars. In about 15 per cent of these binaries, the magnetic field of the white dwarf is strong enough (at 106 gauss or more) to channel the accreted matter along field lines onto the magnetic poles1,2. The remaining systems are referred to as ‘non-magnetic’, because until now there has been no evidence that they have a magnetic field that is strong enough to affect the accretion dynamics. Here we report an analysis of archival optical observations of the ‘non-magnetic’ accreting white dwarf in the binary system MV Lyrae, whose light curve displays quasi-periodic bursts of about 30 minutes duration roughly every 2 hours. The timescale and amplitude of these bursts indicate the presence of an unstable, magnetically regulated accretion mode, which in turn implies the existence of magnetically gated accretion3,4,5, in which disk material builds up around the magnetospheric boundary (at the co-rotation radius) and then accretes onto the white dwarf, producing bursts powered by the release of gravitational potential energy. We infer a surface magnetic field strength for the white dwarf in MV Lyrae of between 2 × 104 gauss and 1 × 105 gauss, too low to be detectable by other current methods. Our discovery provides a new way of studying the strength and evolution of magnetic fields in accreting white dwarfs and extends the connections between accretion onto white dwarfs, young stellar objects and neutron stars, for which similar magnetically gated accretion cycles have been identified6,7,8,9.
Citation
Scaringi, S., Maccarone, T., D’Angelo, C., Knigge, C., & Groot, P. (2017). Magnetically gated accretion in an accreting ‘non-magnetic’ white dwarf. Nature, 552(7684), 210-213. https://doi.org/10.1038/nature24653
Journal Article Type | Article |
---|---|
Acceptance Date | Oct 16, 2017 |
Online Publication Date | Dec 14, 2017 |
Publication Date | 2017 |
Deposit Date | Dec 31, 2020 |
Publicly Available Date | Jun 30, 2021 |
Journal | Nature |
Print ISSN | 0028-0836 |
Electronic ISSN | 1476-4687 |
Publisher | Nature Research |
Peer Reviewed | Peer Reviewed |
Volume | 552 |
Issue | 7684 |
Pages | 210-213 |
DOI | https://doi.org/10.1038/nature24653 |
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