Towards self-consistent modelling of the Sgr A* accretion flow: linking theory and observation

Roberts, Shawn R.; Jiang, Yan-Fei; Wang, Q. Daniel; Ostriker, Jeremiah P.

doi:10.1093/mnras/stw2995

Cited by 30 publications

(39 citation statements)

References 42 publications

(130 reference statements)

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“…Extend this to our understanding of SgrA * , with the fiducial Bondi radius of 3 7 (Wang et al 2013). The brightness from the inner scattering halo is comparable to the fraction of quiescent SgrA * flux that has been attributed to unresolved flares (10%, Neilsen et al 2013) and to point-like emission (4%, Roberts et al 2017). …”

Section: Discussionmentioning

confidence: 67%

“…Furthermore, the ISM column obtained from X-ray absorption does not match that obtained from extinction measurements in the infrared (Fritz et al 2011); they differ by a factor of two. Finally, Chandra observations have revealed that the X-ray emission from SgrA * is extended, allowing us to test theoretical models that trace the flow of hot gas as it falls into the supermassive black hole (Baganoff et al 2003;Shcherbakov & Baganoff 2010;Wang et al 2013;Roberts et al 2017). This situation is complicated by the fact that SgrA * is variable, flaring on the order of once per day for hours at a time (e.g., Neilsen et al 2013) and impacting neutral gas in the vicinity of the GC (e.g., Krivonos et al 2016).…”

Section: Introductionmentioning

confidence: 99%

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The Chandra Dust-scattering Halo of Galactic Center Transient Swift J174540.7–290015

Corrales

Mon

Haggard

et al. 2017

ApJ

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We report the detection of a dust-scattering halo around a recently discovered X-ray transient, Swift J174540.7-290015, which in early 2016 February underwent one of the brightest outbursts (F X ≈ 5 × 10 −10 erg cm −2 s −1 ) observed from a compact object in the Galactic Center field. We analyze four Chandra images that were taken as follow-up observations to Swift discoveries of new Galactic Center transients. After adjusting our spectral extraction for the effects of detector pile-up, we construct a point-spread function for each observation and compare it to the GC field before the outburst. We find residual surface brightness around Swift J174540.7-290015, which has a shape and temporal evolution consistent with the behavior expected from X-rays scattered by foreground dust. We examine the spectral properties of the source, which shows evidence that the object transitioned from a soft to hard spectral state as it faded below L X ∼10 36 ergs −1 . This behavior is consistent with the hypothesis that the object is a low-mass X-ray binary in the Galactic Center.

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Section: Discussionmentioning

confidence: 67%

Section: Introductionmentioning

confidence: 99%

The Chandra Dust-scattering Halo of Galactic Center Transient Swift J174540.7–290015

Corrales

Mon

Haggard

et al. 2017

ApJ

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“…Consequently, most of the material accreting through the Bondi radius must be ejected in an outflow of some kind (e.g., Sadowski et al 2013;Yuan & Narayan 2014;Yuan et al 2015;Roberts et al 2017). Both jets and broadly collimated winds have been considered, but the nature of the outflow remains to be observationally determined.…”

Section: Discussionmentioning

confidence: 99%

A Nonthermal Radio Filament Connected to the Galactic Black Hole?

Morris

Zhao

Goss

2017

ApJL

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Using the Very Large Array, we have investigated a nonthermal radio filament (NTF) recently found very near the Galactic black hole and its radio counterpart, SgrA * . While this NTF-the Sgr A West Filament (SgrAWF)-shares many characteristics with the population of NTFs occupying the central few hundred parsecs of the Galaxy, the SgrAWF has the distinction of having an orientation and sky location that suggest an intimate physical connection to SgrA * . We present 3.3 and 5.5 cm images constructed using an innovative methodology that yields a very high dynamic range, providing an unprecedentedly clear picture of the SgrAWF. While the physical association of the SgrAWF with SgrA * is not unambiguous, the images decidedly evoke this interesting possibility. Assuming that the SgrAWF bears a physical relationship to SgrA * , we examine the potential implications. One is that SgrA * is a source of relativistic particles constrained to diffuse along ordered local field lines. The relativistic particles could also be fed into the local field by a collimated outflow from SgrA * , perhaps driven by the Poynting flux accompanying the black hole spin in the presence of a magnetic field threading the event horizon. Second, we consider the possibility that the SgrAWF is the manifestation of a low-mass-density cosmic string that has become anchored to the black hole. The simplest form of these hypotheses would predict that the filament be bi-directional, whereas the SgrAWF is only seen on one side of SgrA * , perhaps because of the dynamics of the local medium.

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“…Could such a radiatively inefficient IMBH explain the possible point-like component of the X-ray emission? In the hot accretion case, the spatial distributions of the plasma density and temperature of the accretion flow can be scaled with their values at the so-called Bondi radius r b ∝ M IMBH (e.g., Roberts et al 2017). This radius characterizes the size of the region in which the plasma of certain thermal and/or kinematic properties can be initially captured by the gravity of the black hole.…”

Section: Constraints On X-ray Emission From the Putative Imbhmentioning

confidence: 99%

“…This radius characterizes the size of the region in which the plasma of certain thermal and/or kinematic properties can be initially captured by the gravity of the black hole. Although the Bondi accretion model itself is typically too simplistic to describe the complex accretion process, the X-ray emission from the hot gas accretion is qualitatively dominated by the outer accretion flow (e.g., Wang et al 2013;Roberts et al 2017). One may then expect that L x ∝ r 3 b n 2 e ∝ M 3 IMBH n 2 e .…”

Section: Constraints On X-ray Emission From the Putative Imbhmentioning

confidence: 99%

Colliding winds in and around the stellar group IRS 13E at the galactic centre

Wang

Russell

et al. 2019

Monthly Notices of the Royal Astronomical Society

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IRS 13E is an enigmatic compact group of massive stars located in projection only 3. 6 away from Sgr A*. This group has been suggested to be bounded by an intermediate-mass black hole (IMBH). We present a multi-wavelength study of the group and its interplay with the environment. Based on Chandra observations, we find the X-ray spectrum of IRS 13E can be well characterized by an optically thin thermal plasma. The emission peaks between two strongly mass-losing Wolf-Rayet stars of the group. These properties can be reasonably well reproduced by simulated colliding winds of these two stars. However, this scenario underpredicts the X-ray intensity in outer regions. The residual emission likely results from the ram-pressure confinement of the IRS 13E group wind by the ambient medium and is apparently associated with a shell-like warm gas structure seen in Pa-alpha and in ALMA observations. These latter observations also show strongly peaked thermal emission with unusually large velocity spread between the two stars. These results indicate that the group is colliding with the bar of the dense cool gas mini-spiral around Sgr A*. The extended X-ray morphology of IRS 13E and its association with the bar further suggest that the group is physically much farther away than the projected distance from Sgr A*. The presence of an IMBH, while favorable to keep the stars bound together, is not necessary to explain the observed stellar and gas properties of IRS 13E.

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Towards self-consistent modelling of the Sgr A* accretion flow: linking theory and observation

Cited by 30 publications

References 42 publications

The Chandra Dust-scattering Halo of Galactic Center Transient Swift J174540.7–290015

The Chandra Dust-scattering Halo of Galactic Center Transient Swift J174540.7–290015

A Nonthermal Radio Filament Connected to the Galactic Black Hole?

Colliding winds in and around the stellar group IRS 13E at the galactic centre

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