Ticking away: the long-term X-ray timing and spectral evolution of eRO-QPE2
Ticking away: the long-term X-ray timing and spectral evolution of eRO-QPE2
Quasi-periodic eruptions (QPEs) are repeated X-ray flares from galactic nuclei that recur every few hours to days, depending on the source. Despite some diversity in the recurrence and amplitude of eruptions, their striking regularity has motivated theorists to associate QPEs with orbital systems. Among the known QPE sources, eRO-QPE2 has shown the most regular flare timing and luminosity since its discovery. We report here on its long-term evolution over 3.3 yr from discovery and find that: i) the average QPE recurrence time per epoch has decreased over time, albeit not at a uniform rate; ii) the distinct alternation between consecutive long and short recurrence times found at discovery has not been significant since; iii) the spectral properties, namely flux and temperature of both eruptions and quiescence components, have remained remarkably consistent within uncertainties. We attempted to interpret these results as orbital period and eccentricity decay coupled with orbital and disk precession. However, since gaps between observations are too long, we are not able to distinguish between an evolution dominated by just a decreasing trend, or by large modulations (e.g. due to the precession frequencies at play). In the former case, the observed period decrease is roughly consistent with that of a star losing orbital energy due to hydrodynamic gas drag from disk collisions, although the related eccentricity decay is too fast and additional modulations have to contribute too. In the latter case, no conclusive remarks are possible on the orbital evolution and the nature of the orbiter due to the many effects at play. However, these two cases come with distinctive predictions for future X-ray data: in the case of a decreasing trend, we expect all future observations to show a shorter recurrence time than the latest epoch, while in the case of large-amplitude modulations we expect some future observations to be found with a larger recurrence, hence an apparent temporary period increase.
astro-ph.GA, astro-ph.HE, Galaxies: nuclei, X-rays: galaxies, Accretion, accretion disks, Galaxies: dwarf
Arcodia, R.
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Linial, I.
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Miniutti, G.
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Franchini, A.
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Giustini, M.
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Bonetti, M.
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Sesana, A.
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Soria, R.
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Chakraborty, J.
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Dotti, M.
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Kara, E.
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Merloni, A.
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Ponti, G.
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Vincentelli, F.
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Arcodia, R.
b712afb2-4c60-4776-8845-850a74dc41b4
Linial, I.
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Miniutti, G.
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Franchini, A.
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Giustini, M.
95252c16-b214-4a63-bc56-1614149c2e38
Bonetti, M.
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Sesana, A.
55ceb36d-17d3-4527-b63a-81c2f5944dd4
Soria, R.
c3d2d954-57ee-49b8-8e52-5155be901228
Chakraborty, J.
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Dotti, M.
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Kara, E.
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Merloni, A.
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Ponti, G.
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Vincentelli, F.
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Arcodia, R., Linial, I., Miniutti, G., Franchini, A., Giustini, M., Bonetti, M., Sesana, A., Soria, R., Chakraborty, J., Dotti, M., Kara, E., Merloni, A., Ponti, G. and Vincentelli, F.
(2024)
Ticking away: the long-term X-ray timing and spectral evolution of eRO-QPE2.
Astronomy & Astrophysics, 690, [A80].
(doi:10.1051/0004-6361/202451218).
Abstract
Quasi-periodic eruptions (QPEs) are repeated X-ray flares from galactic nuclei that recur every few hours to days, depending on the source. Despite some diversity in the recurrence and amplitude of eruptions, their striking regularity has motivated theorists to associate QPEs with orbital systems. Among the known QPE sources, eRO-QPE2 has shown the most regular flare timing and luminosity since its discovery. We report here on its long-term evolution over 3.3 yr from discovery and find that: i) the average QPE recurrence time per epoch has decreased over time, albeit not at a uniform rate; ii) the distinct alternation between consecutive long and short recurrence times found at discovery has not been significant since; iii) the spectral properties, namely flux and temperature of both eruptions and quiescence components, have remained remarkably consistent within uncertainties. We attempted to interpret these results as orbital period and eccentricity decay coupled with orbital and disk precession. However, since gaps between observations are too long, we are not able to distinguish between an evolution dominated by just a decreasing trend, or by large modulations (e.g. due to the precession frequencies at play). In the former case, the observed period decrease is roughly consistent with that of a star losing orbital energy due to hydrodynamic gas drag from disk collisions, although the related eccentricity decay is too fast and additional modulations have to contribute too. In the latter case, no conclusive remarks are possible on the orbital evolution and the nature of the orbiter due to the many effects at play. However, these two cases come with distinctive predictions for future X-ray data: in the case of a decreasing trend, we expect all future observations to show a shorter recurrence time than the latest epoch, while in the case of large-amplitude modulations we expect some future observations to be found with a larger recurrence, hence an apparent temporary period increase.
Text
2406.17020v2
- Author's Original
Text
aa51218-24
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Accepted/In Press date: 19 July 2024
e-pub ahead of print date: 2 October 2024
Keywords:
astro-ph.GA, astro-ph.HE, Galaxies: nuclei, X-rays: galaxies, Accretion, accretion disks, Galaxies: dwarf
Identifiers
Local EPrints ID: 496476
URI: http://eprints.soton.ac.uk/id/eprint/496476
ISSN: 0004-6361
PURE UUID: b0354c9e-ab2c-4c7c-bb0d-3b6b63ec4515
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Date deposited: 16 Dec 2024 17:44
Last modified: 16 Dec 2024 17:48
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Contributors
Author:
R. Arcodia
Author:
I. Linial
Author:
G. Miniutti
Author:
A. Franchini
Author:
M. Giustini
Author:
M. Bonetti
Author:
A. Sesana
Author:
R. Soria
Author:
J. Chakraborty
Author:
M. Dotti
Author:
E. Kara
Author:
A. Merloni
Author:
G. Ponti
Author:
F. Vincentelli
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