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High energy Millihertz quasi-periodic oscillations in 1A 0535+262 with Insight-HXMT challenge current models

High energy Millihertz quasi-periodic oscillations in 1A 0535+262 with Insight-HXMT challenge current models
High energy Millihertz quasi-periodic oscillations in 1A 0535+262 with Insight-HXMT challenge current models

We studied the millihertz quasi-periodic oscillation (mHz QPO) in the 2020 outburst of the Be/X-ray binary 1A 0535 + 262 using Insight-HXMT data over a broad energy band. The mHz QPO is detected in the 27–120 keV energy band. The QPO centroid frequency is correlated with the source flux and evolves in the 35–95 mHz range during the outburst. The QPO is most significant in the 50–65 keV band, with a significance of ∼8σ, but is hardly detectable (<2σ) in the lowest (1–27 keV) and highest (>120 keV) energy bands. Notably, the detection of mHz QPO above 80 keV is the highest energy at which mHz QPOs have been detected so far. The fractional rms of the mHz QPO first increases and then decreases with energy, reaching the maximum amplitude at 50–65 keV. In addition, at the peak of the outburst, the mHz QPO shows a double-peak structure, with the difference between the two peaks being constant at ∼0.02 Hz, twice the spin frequency of the neutron star in this system. We discuss different scenarios explaining the generation of the mHz QPO, including the beat frequency model, the Keplerian frequency model, the model of two jets in opposite directions, and the precession of the neutron star, but find that none of them can explain the origin of the QPO well. We conclude that the variability of non-thermal radiation may account for the mHz QPO, but further theoretical studies are needed to reveal the physical mechanism.

X-rays: binaries, pulsars: individual: (1A 0535 + 262), stars: neutron
1365-2966
1988-1999
Ma, Ruican
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Tao, Lian
75749bbb-a4e9-4734-8325-6180e5dad82b
Zhang, Shuang-Nan
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Ji, Long
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Zhang, Liang
216ccbc3-5449-42f1-83af-4303376c07b4
Bu, Qingcui
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Qu, Jinlu
f062632f-d68b-474a-bf6e-a73860fbe41f
Reig, Pablo
5ad0672e-f191-474d-9339-5b26aba89633
Méndez, Mariano
5cc6f759-dae2-488a-9cc2-cff89f4eca72
Wang, Yanan
1cde6df5-bf7a-43ac-9e75-7560cd7e7e3d
Ma, Xiang
e00054e2-db8d-44c6-be6c-7cf807f0f6d3
Huang, Yue
b61d46a7-90a8-4c1f-bd59-de326fc2eb87
Ge, Mingyu
ca9c5228-ca81-442c-8308-4af364da1a7d
Song, Liming
75034b54-9bff-4e3b-a5d9-44f3525c5513
Zhang, Shu
9e2521e3-dc98-4300-a5a0-ee81f7657c19
Liu, Hexin
16ee1577-6a7f-4f4d-92d6-dacfccf9d76d
Wang, Pengju
af7421db-2358-48de-8520-240feb717dc4
Kong, Lingda
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Ren, Xiaoqin
a80acf61-27c0-4cc5-a182-957901e2babc
Zhao, Shujie
51e060ca-7852-44ed-bdc6-e544a4f23239
Yu, Wei
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Yang, Zixu
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Li, Panping
a873544c-58a1-4f70-9e2b-9c04d8f01c42
Jia, Shumei
ebd34dbb-077b-426e-9494-ccd160abe113
Ma, Ruican
fdb27104-6519-4d64-aa29-6dc665592219
Tao, Lian
75749bbb-a4e9-4734-8325-6180e5dad82b
Zhang, Shuang-Nan
3cb9d0a2-8546-43d8-a94c-2b5816c42bd3
Ji, Long
2db48b7a-5650-4e3f-92fc-aab56b173fec
Zhang, Liang
216ccbc3-5449-42f1-83af-4303376c07b4
Bu, Qingcui
fae2b254-8ba9-43f8-90c1-f7275c1b0281
Qu, Jinlu
f062632f-d68b-474a-bf6e-a73860fbe41f
Reig, Pablo
5ad0672e-f191-474d-9339-5b26aba89633
Méndez, Mariano
5cc6f759-dae2-488a-9cc2-cff89f4eca72
Wang, Yanan
1cde6df5-bf7a-43ac-9e75-7560cd7e7e3d
Ma, Xiang
e00054e2-db8d-44c6-be6c-7cf807f0f6d3
Huang, Yue
b61d46a7-90a8-4c1f-bd59-de326fc2eb87
Ge, Mingyu
ca9c5228-ca81-442c-8308-4af364da1a7d
Song, Liming
75034b54-9bff-4e3b-a5d9-44f3525c5513
Zhang, Shu
9e2521e3-dc98-4300-a5a0-ee81f7657c19
Liu, Hexin
16ee1577-6a7f-4f4d-92d6-dacfccf9d76d
Wang, Pengju
af7421db-2358-48de-8520-240feb717dc4
Kong, Lingda
e91f4c46-0307-4ae1-a6eb-82cb9c28d97f
Ren, Xiaoqin
a80acf61-27c0-4cc5-a182-957901e2babc
Zhao, Shujie
51e060ca-7852-44ed-bdc6-e544a4f23239
Yu, Wei
86977b56-7eae-4fab-a3c1-e990bb7f7490
Yang, Zixu
5bacfc3e-0e9e-4f40-bcba-5d08250b68ca
Li, Panping
a873544c-58a1-4f70-9e2b-9c04d8f01c42
Jia, Shumei
ebd34dbb-077b-426e-9494-ccd160abe113

Ma, Ruican, Tao, Lian, Zhang, Shuang-Nan, Ji, Long, Zhang, Liang, Bu, Qingcui, Qu, Jinlu, Reig, Pablo, Méndez, Mariano, Wang, Yanan, Ma, Xiang, Huang, Yue, Ge, Mingyu, Song, Liming, Zhang, Shu, Liu, Hexin, Wang, Pengju, Kong, Lingda, Ren, Xiaoqin, Zhao, Shujie, Yu, Wei, Yang, Zixu, Li, Panping and Jia, Shumei (2022) High energy Millihertz quasi-periodic oscillations in 1A 0535+262 with Insight-HXMT challenge current models. Monthly Notices of the Royal Astronomical Society, 517 (2), 1988-1999. (doi:10.1093/mnras/stac2768).

Record type: Article

Abstract

We studied the millihertz quasi-periodic oscillation (mHz QPO) in the 2020 outburst of the Be/X-ray binary 1A 0535 + 262 using Insight-HXMT data over a broad energy band. The mHz QPO is detected in the 27–120 keV energy band. The QPO centroid frequency is correlated with the source flux and evolves in the 35–95 mHz range during the outburst. The QPO is most significant in the 50–65 keV band, with a significance of ∼8σ, but is hardly detectable (<2σ) in the lowest (1–27 keV) and highest (>120 keV) energy bands. Notably, the detection of mHz QPO above 80 keV is the highest energy at which mHz QPOs have been detected so far. The fractional rms of the mHz QPO first increases and then decreases with energy, reaching the maximum amplitude at 50–65 keV. In addition, at the peak of the outburst, the mHz QPO shows a double-peak structure, with the difference between the two peaks being constant at ∼0.02 Hz, twice the spin frequency of the neutron star in this system. We discuss different scenarios explaining the generation of the mHz QPO, including the beat frequency model, the Keplerian frequency model, the model of two jets in opposite directions, and the precession of the neutron star, but find that none of them can explain the origin of the QPO well. We conclude that the variability of non-thermal radiation may account for the mHz QPO, but further theoretical studies are needed to reveal the physical mechanism.

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Accepted/In Press date: 20 September 2022
Published date: 1 December 2022
Additional Information: Funding Information: We thank the anonymous referee and Yuexin Zhang for useful comments that have improved the paper. This work made use of data from the Insight-HXMT mission, a project funded by China National Space Administration (CNSA) and the Chinese Academy of Sciences (CAS). This work is supported by the National Key R&D Program of China (2021YFA0718500). We acknowledge funding support from the National Natural Science Foundation of China (NSFC) under grant nos. 12122306, U1838115, U1838201, U1838202, 12173103, U2038101, U1938103, and 11733009, the CAS Pioneer Hundred Talent Program Y8291130K2, and the Scientific and technological innovation project of IHEP Y7515570U1. This work was partially supported by International Partnership Program of Chinese Academy of Sciences (grant no. 113111KYSB20190020). RM acknowledges support from China Scholarship Council (CSC 202104910402). MM acknowledges the research programme Athena with project number 184.034.002, which is (partly) financed by the Dutch Research Council (NWO). Facilities: Insight-HXMT. Publisher Copyright: © 2022 The Author(s)
Keywords: X-rays: binaries, pulsars: individual: (1A 0535 + 262), stars: neutron

Identifiers

Local EPrints ID: 472607
URI: http://eprints.soton.ac.uk/id/eprint/472607
ISSN: 1365-2966
PURE UUID: 90067a67-1c78-4e08-93d8-48585b91d103

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Date deposited: 12 Dec 2022 17:33
Last modified: 29 Nov 2024 15:50

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Contributors

Author: Ruican Ma
Author: Lian Tao
Author: Shuang-Nan Zhang
Author: Long Ji
Author: Liang Zhang
Author: Qingcui Bu
Author: Jinlu Qu
Author: Pablo Reig
Author: Mariano Méndez
Author: Yanan Wang
Author: Xiang Ma
Author: Yue Huang
Author: Mingyu Ge
Author: Liming Song
Author: Shu Zhang
Author: Hexin Liu
Author: Pengju Wang
Author: Lingda Kong
Author: Xiaoqin Ren
Author: Shujie Zhao
Author: Wei Yu
Author: Zixu Yang
Author: Panping Li
Author: Shumei Jia

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