Three evolutionary paths for magnetar oscillations
Three evolutionary paths for magnetar oscillations
Quasi-periodic oscillations (QPOs) have been seen in the light curves following several magnetar giant flares. These oscillations are of great interest as they probably provide our first ever view of the normal modes of oscillation of neutron stars. The state of the art lies in the study of the oscillations of elastic–magnetic stellar models, mainly with a view to relating the observed frequencies to the structure and composition of the star itself. We advance this programme by considering several new physical mechanisms that are likely to be important for magnetar oscillations. These relate to the superfluid/superconducting nature of the stellar interior and the damping of the modes, both through internal dissipation mechanisms and the launching of waves into the magnetosphere. We make simple order-of-magnitude estimates to show that both the frequencies and the damping time of magnetar oscillations can evolve in time, identifying three distinct ‘pathways’ that can be followed, depending upon the initial magnitude of the mode excitation. These results are interesting as they show that the information buried in magnetar QPOs may be even richer than previously thought, and motivate more careful examination of magnetar light curves, to search for signatures of the different types of evolution that we have identified.
dense matter, stars: magnetars, stars: neutron, stars: oscillations
1522-1535
Glampedakis, K.
bece2036-f721-468e-9cd2-cf4324ff2deb
Jones, D.I.
b8f3e32c-d537-445a-a1e4-7436f472e160
1 April 2014
Glampedakis, K.
bece2036-f721-468e-9cd2-cf4324ff2deb
Jones, D.I.
b8f3e32c-d537-445a-a1e4-7436f472e160
Glampedakis, K. and Jones, D.I.
(2014)
Three evolutionary paths for magnetar oscillations.
Monthly Notices of the Royal Astronomical Society, 439 (2), .
(doi:10.1093/mnras/stu017).
Abstract
Quasi-periodic oscillations (QPOs) have been seen in the light curves following several magnetar giant flares. These oscillations are of great interest as they probably provide our first ever view of the normal modes of oscillation of neutron stars. The state of the art lies in the study of the oscillations of elastic–magnetic stellar models, mainly with a view to relating the observed frequencies to the structure and composition of the star itself. We advance this programme by considering several new physical mechanisms that are likely to be important for magnetar oscillations. These relate to the superfluid/superconducting nature of the stellar interior and the damping of the modes, both through internal dissipation mechanisms and the launching of waves into the magnetosphere. We make simple order-of-magnitude estimates to show that both the frequencies and the damping time of magnetar oscillations can evolve in time, identifying three distinct ‘pathways’ that can be followed, depending upon the initial magnitude of the mode excitation. These results are interesting as they show that the information buried in magnetar QPOs may be even richer than previously thought, and motivate more careful examination of magnetar light curves, to search for signatures of the different types of evolution that we have identified.
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e-pub ahead of print date: 13 February 2014
Published date: 1 April 2014
Keywords:
dense matter, stars: magnetars, stars: neutron, stars: oscillations
Organisations:
Physics & Astronomy
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Local EPrints ID: 369401
URI: http://eprints.soton.ac.uk/id/eprint/369401
ISSN: 1365-2966
PURE UUID: 86b14897-9d73-4027-8ef4-db0df8c7aec7
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Date deposited: 25 Sep 2014 11:53
Last modified: 15 Mar 2024 03:01
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Author:
K. Glampedakis
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