Pulsating ULXs: large pulsed fraction excludes strong beaming

Mushtukov, Alexander A.; Zwart, Simon Portegies; Tsygankov, Sergey S.; Нагирнер, Д. И.; Poutanen, Juri

doi:10.1093/mnras/staa3809

Cited by 52 publications

(54 citation statements)

References 36 publications

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“…Determining the underlying ULX demographic presently relies on detecting unambiguous indicators for the presence of a neutron star such as pulsations or a CRSF. However, it has been proposed that many NS ULXs with high accretion rates may not exhibit pulsations King et al (2017), that large pulse fractions may be absent in the presence of strong beaming (Mushtukov et al 2021b), and CRSFs may not fall within the accessible X-ray energy range or may be diluted (see Mushtukov et al 2017a). An independent and simple method to constrain the nature of the underlying population in ULXs such as the one we have explored here is therefore of value (and joins others such as observing the evolution of quasi-periodic oscillations, see Middleton et al 2019b).…”

Section: Discussionmentioning

confidence: 99%

“…Under the assumption that geometrical beaming acts to some extent across the entire ULX population (i.e. ignoring the presence of very strong magnetic fields -see King & Lasota 2019 but also Mushtukov et al 2021a), the proportion of neutron stars and black holes within the ULX population has been analytically estimated by Middleton & King (2017), while estimates leveraging binary population synthesis have also recently been explored (Wiktorowicz et al 2019). Both studies predict that, whilst NS systems almost certainly dominate the entire intrinsic population of ULXs, observationally the populations of NS and BH ULXs may be comparable (particularly for host regions with low metallicity), although this may be in conflict with spectral similarities between the brightest ULXs (typically > a few × 10 39 erg s −1 ) and those systems confirmed to harbour neutron stars (Pinto et al 2017;Walton et al 2018).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

The impact of precession on the observed population of ULXs

Khan

Middleton

Wiktorowicz

et al. 2021

Monthly Notices of the Royal Astronomical Society

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The discovery of neutron stars powering several ultraluminous X-ray sources (ULXs) raises important questions about the nature of the underlying population. In this paper we build on previous work studying simulated populations by incorporating a model where the emission originates from a precessing, geometrically beamed wind-cone, created by a super-critical inflow. We obtain estimates – independent of the prescription for the precession period of the wind – for the relative number of ULXs that are potentially visible (persistent or transient) for a range of underlying factors such as the relative abundance of black holes or neutron stars within the population, maximum precessional angle, and LMXB duty cycle. We make initial comparisons to existing data using a catalogue compiled from XMM-Newton. Finally, based on estimates for the precession period, we determine how the eROSITA all-sky survey (eRASS) will be able to constrain the underlying demographic.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The impact of precession on the observed population of ULXs

Khan

Middleton

Wiktorowicz

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…(King et al 2017), would need to be revisited in the context of ULXPs. Small beaming is also consistent with the detection of pulsations in ULXPs, as large beaming factors would otherwise result in very small pulsed fractions (Mushtukov et al 2021). The above suggests that strong beaming is not needed for ULXPs, and this should be considered in the framework of ULX population synthesis (e.g., Misra et al 2020;Abdusalam et al 2020;Kuranov et al 2020) and perhaps gravitational wave progenitors, which are thought to go through a ULX phase (Marchant et al 2017).…”

Section: Constraints On Orbit Inclination and Ulx Beamingmentioning

confidence: 60%

Chandra Probes the X-Ray Variability of M51 ULX-7: Evidence of Propeller Transition and X-Ray Dips on Orbital Periods

Vasilopoulos

Koliopanos

Haberl

et al. 2021

ApJ

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We report on the temporal properties of the ultraluminous X-ray (ULX) pulsar M51 ULX-7 inferred from the analysis of the 2018-2020 Swift/X-ray Telescope monitoring data and archival Chandra data obtained over a period of 33 days in 2012. We find an extended low flux state, which might be indicative of propeller transition, lending further support to the interpretation that the neutron star is rotating near equilibrium. Alternatively, this offstate could be related to a variable superorbital period. Moreover, we report the discovery of periodic dips in the X-ray light curve that are associated with the binary orbital period. The presence of the dips implies a configuration where the orbital plane of the binary is closer to an edge-on orientation, and thus demonstrates that favorable geometries are not necessary in order to observe ULX pulsars. These characteristics are similar to those seen in prototypical X-ray pulsars such as Her X-1 and SMC X-1 or other ULX pulsars such as NGC 5907 ULX1.

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“…In a possible alternative scenario, the increasingly brighter hard tail, from SSUL to SUL, could be produced by an increase in the accretion rate which boosts the emission from the inner super-Eddington regions, followed by further scattering through the outer disc/wind (Walton et al 2020;Gúrpide et al 2021). This has been invoked to explain the lower pulse fraction at higher X-ray fluxes of some ULXs (Mushtukov et al 2021;Robba et al 2021).…”

Section: The Normal Branch: From Ssul To Sulmentioning

confidence: 95%

The Chameleon on the branches: spectral state transition and dips in NGC 247 ULX-1

D’Aí

Pinto

Santo

et al. 2021

Monthly Notices of the Royal Astronomical Society

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Soft Ultra-Luminous X-ray (ULXs) sources are a sub-class of the ULXs that can switch from a supersoft spectral state, where most of the luminosity is emitted below 1 keV, to a soft spectral state with significant emission above 1 keV. In a few systems, dips have been observed. The mechanism behind this state transition and the dips nature are still debated. To investigate these issues, we obtained a long XMM-Newton monitoring campaign of a member of this class, NGC 247 ULX-1. We computed the hardness-intensity diagram for the whole data-set and identified two different branches: the normal branch and the dipping branch, which we study with four and three hardness-intensity resolved spectra, respectively. All seven spectra are well described by two thermal components: a colder (kTbb ∼ 0.1-0.2 keV) black-body, interpreted as emission from the photo-sphere of a radiatively-driven wind, and a hotter (kTdisk ∼ 0.6 keV) multi-colour disk black-body, likely due to reprocessing of radiation emitted from the innermost regions. In addition, a complex pattern of emission and absorption lines has been taken into account based on previous high-resolution spectroscopic results. We studied the evolution of spectral parameters and flux of the two thermal components along the two branches and discuss two scenarios possibly connecting the state transition and the dipping phenomenon. One is based on geometrical occultation of the emitting regions, the other invokes the onset of a propeller effect.

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Pulsating ULXs: large pulsed fraction excludes strong beaming

Cited by 52 publications

References 36 publications

The impact of precession on the observed population of ULXs

The impact of precession on the observed population of ULXs

Chandra Probes the X-Ray Variability of M51 ULX-7: Evidence of Propeller Transition and X-Ray Dips on Orbital Periods

The Chameleon on the branches: spectral state transition and dips in NGC 247 ULX-1

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