Multiple Shock Fronts in RBS 797: The Chandra Window on Shock Heating in Galaxy Clusters

Ubertosi, Francesco; Gitti, Myriam; Brighenti, Fabrizio; McDonald, Michael; Nulsen, P. E. J.; Donahue, M.; Brunetti, G.; Randall, Scott W.; Gaspari, M.; Ettori, S.; Calzadilla, Michael S.; Ignesti, Alessandro; Feretti, L.; Blanton, E. L.

doi:10.3847/1538-4357/acacf9

Cited by 8 publications

(5 citation statements)

References 118 publications

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“…We find the Mach number for this shell-like shock surface to be approximately 1.5 S  . The above result further supports the argument that the presence of multiple shock fronts associated with a jet in such an ambient medium implies an older jet reorientation activity, similar to, e.g., Ubertosi et al (2023). The presence of these differently aligned shocks also demonstrates the enhanced disruptive capability of jetted structures with bent morphologies, strongly supporting the idea that these structures can cause the isotropic heating of galaxy clusters, as has been reported in a number of recent studies (e.g., see Cielo et al 2018).…”

Section: Reference Casesupporting

confidence: 85%

“…A recently discovered X-ray cavity system in the galaxy cluster RBS 797 (Ubertosi et al 2021) further demonstrates the existence of an analogous example in the deep-exposure X-ray map, validating the jet-reorientation hypothesis from their multiband observations. This geometrically complex cavity distribution is surrounded by a shocked surface farther out, as also seen in Ubertosi et al (2023), resembling our acquired X-ray map, which was formed as a result of the expansion of the older jet, and consequently, of the wing expansion.…”

Section: Viewing Effects On the Cavity Morphologysupporting

confidence: 69%

“…For example, Ubertosi et al (2021) have identified two pairs of cavities that are located at similar distances from the cluster center and are aligned perpendicular to each other (see also Bogdán et al 2014). An even more complex example can be found in the Perseus galaxy cluster (Fabian et al 2017), which shows offaxis cavities, rims, and a geometrically complex distribution of pressure waves (also see Ubertosi et al 2023, for the RBS 797 galaxy cluster). Other galaxy groups or clusters with such intricate cavity structures include M84 (Bambic et al 2023), NGC 5813 (Randall et al 2015), A2052 (Blanton et al 2011), NGC 5044 (David et al 2011), Cygnus A (Smith et al 2002), andMS0735.6 +7421 (McNamara et al 2009).…”

Section: Introductionmentioning

confidence: 99%

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Deciphering the Morphological Origins of X-shaped Radio Galaxies: Numerical Modeling of Backflow versus Jet Reorientation

Giri,

Vaidya,

Fendt

2023

ApJS

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X-shaped radio galaxies (XRGs) develop when certain extragalactic jets deviate from their propagation path. An asymmetric ambient medium (backflow model) or complex active galactic nucleus activity (jet-reorientation model) enforcing the jet direction to deviate may cause these structures. In this context, the present investigation focuses on the modeling of XRGs by performing 3D relativistic magnetohydrodynamic simulations. We implement different jet-propagation models applying an initially identical jet-ambient medium configuration to understand distinctive features. This study, the first of its kind, demonstrates that all adopted models produce XRGs with notable properties, thereby challenging the notion of a universal model. Jet reorientation naturally explains several contentious properties of XRGs, including wing alignment along the ambient medium’s primary axis, development of collimated lobes, and the formation of noticeably longer wings than active lobes. These XRGs disrupt the cluster medium by generating isotropic shocks and channeling more energy than in the backflow scenario. Our synthetic thermal X-ray maps of the cluster medium reveal four clear elongated cavities associated with the wing-lobe alignment, regardless of projection effects, but they affect their age estimation. We show that the depth and geometric alignment of the evolved cavities may qualify as promising characteristics of XRGs, which may be used to disentangle different formation scenarios.

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Section: Reference Casesupporting

confidence: 85%

Section: Viewing Effects On the Cavity Morphologysupporting

confidence: 69%

Section: Introductionmentioning

confidence: 99%

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Deciphering the Morphological Origins of X-shaped Radio Galaxies: Numerical Modeling of Backflow versus Jet Reorientation

Giri,

Vaidya,

Fendt

2023

ApJS

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“…If there are massive structures nearby, the gas mass content of the cluster will naturally be truncated by the Subfind algorithm, and its total gas mass will be smaller. Second, the shocks occurring in the gas can be due to not only mergers between large structures but also the result of active galactic nucleus (AGN) feedback (Ubertosi et al 2023). I verified, however, that the significant AGN feedback was present in the main clusters and subclusters only at higher redshifts of z = 2 − 3, so it does not contribute to the creation of large-scale bow shocks at z = 0.…”

Section: Discussionmentioning

confidence: 85%

Merging galaxy clusters in IllustrisTNG

Lokas¹

2023

A&A

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Mergers between galaxy clusters are an important stage in the formation of the large-scale structure of the Universe. Some of the mergers show a spectacular bow shock that formed as a result of recent passage of a smaller cluster through a bigger one, the classic example of this being the so-called bullet cluster. In this paper, I describe ten examples of interacting clusters identified among 200 of the most massive objects, with total masses above 1.4 × 10 14 M , from the IllustrisTNG300 simulation by searching for prominent bow shocks in their temperature maps. Despite different mass ratios of the two merging clusters, the events are remarkably similar in many respects. In all cases, the companion cluster passed close to the main one only once, between 0.9 and 0.3 Gyr ago, with the pericenter distance of 100-530 kpc and a velocity of up to 3400 km s −1 . The subcluster, typically an order of magnitude smaller in mass than the main cluster before the interaction, loses most of its dark matter and gas in the process. The displacement between the collisionless part of the remnant and the bow shock is such that the remnant typically lags behind the shock or coincides with it, with a single exception of the merger occurring with the largest velocity. Usually about 1% of the gas cells in the merging clusters are shocked, and the median Mach numbers of these gas cells are around two. Due to the relatively small size of the simulation box, no close analog of the bullet cluster was found, but I identified one case that is similar in terms of mass, velocity, and displacement. The presented cases bear more resemblance to less extreme observed interacting clusters such as A520 and Coma.

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“…It also shows the ejective mode where the gas is pushed out of the galaxy, and the preventive mode of feedback, in which the hot halo is prevented from cooling and condensing onto the galaxy to form stars. Rizza et al 1999;Tremblay et al 2012;Ubertosi et al 2023;Pandge et al 2021;Liu et al 2020;Vagshette et al 2019).…”

Section: Agn Driven Feedbackmentioning

confidence: 99%

From birth to maturity: tracing the evolution and impact of radio galaxies

Kukreti

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Multiple Shock Fronts in RBS 797: The Chandra Window on Shock Heating in Galaxy Clusters

Cited by 8 publications

References 118 publications

Deciphering the Morphological Origins of X-shaped Radio Galaxies: Numerical Modeling of Backflow versus Jet Reorientation

Deciphering the Morphological Origins of X-shaped Radio Galaxies: Numerical Modeling of Backflow versus Jet Reorientation

Merging galaxy clusters in IllustrisTNG

From birth to maturity: tracing the evolution and impact of radio galaxies

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