Nonlinear Coupling between Magnetar QPOs

P. Pnigouras; S. K. Lander

doi:10.3847/1538-4357/adceee

Nonlinear Coupling between Magnetar QPOs

P. Pnigouras, S. K. Lander

School of Engineering, Mathematics and Physics

Research output: Contribution to journal › Article › peer-review

Abstract

The quasiperiodic oscillations (QPOs) observed in the tails of magnetar giant γ-ray flares have long been interpreted as normal oscillation modes of these stars. However, most studies modeling QPOs have neglected some key features in the analyses of the signals, namely that QPOs appear to be detectable only intermittently and exhibit drifts in their frequencies. These are typical characteristics of nonlinear mode coupling, where, at leading order, the modes couple and evolve collectively as triplets. Using a representative triplet of modes, we solve the system’s nonlinear equations of motion analytically and argue that the coupling is likely axial-axial-polar in nature, with the observed intermittence and frequency drifts providing a way to infer details of the magnetar’s internal magnetic field geometry.

Original language	English
Article number	35
Journal	Astrophysical Journal
Volume	987
Issue number	1
DOIs	https://doi.org/10.3847/1538-4357/adceee
Publication status	Published - 25 Jun 2025

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title = "Nonlinear Coupling between Magnetar QPOs",

abstract = "The quasiperiodic oscillations (QPOs) observed in the tails of magnetar giant γ-ray flares have long been interpreted as normal oscillation modes of these stars. However, most studies modeling QPOs have neglected some key features in the analyses of the signals, namely that QPOs appear to be detectable only intermittently and exhibit drifts in their frequencies. These are typical characteristics of nonlinear mode coupling, where, at leading order, the modes couple and evolve collectively as triplets. Using a representative triplet of modes, we solve the system{\textquoteright}s nonlinear equations of motion analytically and argue that the coupling is likely axial-axial-polar in nature, with the observed intermittence and frequency drifts providing a way to infer details of the magnetar{\textquoteright}s internal magnetic field geometry.",

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N2 - The quasiperiodic oscillations (QPOs) observed in the tails of magnetar giant γ-ray flares have long been interpreted as normal oscillation modes of these stars. However, most studies modeling QPOs have neglected some key features in the analyses of the signals, namely that QPOs appear to be detectable only intermittently and exhibit drifts in their frequencies. These are typical characteristics of nonlinear mode coupling, where, at leading order, the modes couple and evolve collectively as triplets. Using a representative triplet of modes, we solve the system’s nonlinear equations of motion analytically and argue that the coupling is likely axial-axial-polar in nature, with the observed intermittence and frequency drifts providing a way to infer details of the magnetar’s internal magnetic field geometry.

AB - The quasiperiodic oscillations (QPOs) observed in the tails of magnetar giant γ-ray flares have long been interpreted as normal oscillation modes of these stars. However, most studies modeling QPOs have neglected some key features in the analyses of the signals, namely that QPOs appear to be detectable only intermittently and exhibit drifts in their frequencies. These are typical characteristics of nonlinear mode coupling, where, at leading order, the modes couple and evolve collectively as triplets. Using a representative triplet of modes, we solve the system’s nonlinear equations of motion analytically and argue that the coupling is likely axial-axial-polar in nature, with the observed intermittence and frequency drifts providing a way to infer details of the magnetar’s internal magnetic field geometry.

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Nonlinear Coupling between Magnetar QPOs

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