TY - JOUR
T1 - High energy millihertz quasi-periodic oscillations in 1A 0535 + 262 with Insight-HXMT challenge current models
AU - Ma, Ruican
AU - Tao, Lian
AU - Zhang, Shuang-Nan
AU - Ji, Long
AU - Zhang, Liang
AU - Bu, Qingcui
AU - Qu, Jinlu
AU - Reig, Pablo
AU - Méndez, Mariano
AU - Wang, Yanan
AU - Ma, Xiang
AU - Huang, Yue
AU - Ge, Mingyu
AU - Song, Liming
AU - Zhang, Shu
AU - Liu, Hexin
AU - Wang, Pengju
AU - Kong, Lingda
AU - Ren, Xiaoqin
AU - Zhao, Shujie
AU - Yu, Wei
AU - Yang, Zixu
AU - Li, Panping
AU - Jia, Shumei
PY - 2022/12/1
Y1 - 2022/12/1
N2 - 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 (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.
AB - 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 (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.
KW - stars: neutron
KW - pulsars: individual: (1A 0535 + 262)
KW - X-rays: binaries
KW - Astrophysics - High Energy Astrophysical Phenomena
U2 - 10.1093/mnras/stac2768
DO - 10.1093/mnras/stac2768
M3 - Article
SN - 0035-8711
VL - 517
SP - 1988
EP - 1999
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 2
ER -