2014
DOI: 10.1051/0004-6361/201322456
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Simulation of kinematics of SS 433 radio jets that interact with the ambient medium

Abstract: Context. The mildly relativistic jets of SS 433 are believed to inflate the surrounding supernova remnant W 50, possibly depositing more than 99% of their kinetic energy in the remnant expansion. Where and how this transformation of the energy occurs is as yet unknown. We can learn from this that the jets decelerate and that this deceleration is non-dissipative. Aims. We uncover the deviation of the arcsecond-scale precessing radio jets of SS 433 from the ballistic locus described by the kinematic model as a s… Show more

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Cited by 10 publications
(12 citation statements)
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“…The LSR velocity of the associated gas from radio observations is consistent with those from optical observations. Accordingly, the near kinematic distance of the system is 4.9±0.4 kpc, which agrees well with the results from the kinematic model of the proper motions of the SS 433 jets within the error (e.g., see views in Panferov 2014). The far distance of the system can be excluded due to lacking the H i absorption near the tangent point, e.g., V LSR ∼85 km s −1 .…”
Section: Discussionsupporting
confidence: 88%
“…The LSR velocity of the associated gas from radio observations is consistent with those from optical observations. Accordingly, the near kinematic distance of the system is 4.9±0.4 kpc, which agrees well with the results from the kinematic model of the proper motions of the SS 433 jets within the error (e.g., see views in Panferov 2014). The far distance of the system can be excluded due to lacking the H i absorption near the tangent point, e.g., V LSR ∼85 km s −1 .…”
Section: Discussionsupporting
confidence: 88%
“…Marshall et al (2013)) to a few arcseconds, where it forms a remarkable 'corkscrew' pattern generally consistent with the prediction of the kinematic model (e.g. (MillerJones et al, 2008)), albeit with slight deflections that might be caused by the interaction of the jets with the surrounding medium (Panferov, 2014). Further away, however, the jets stay invisible up to ∼ 10 arcminute scales, where extended X-ray emission, which probably has relation to their propagation through the interstellar medium (ISM), is observed (Brinkmann, * E-mail: khabibullin@iki.rssi.ru Kotani, & Kawai, 2005), and then they appear to be terminated at the boundary of the surrounding radio nebula W50 (Dubner et al, 1998), giving rise to its severe deformation (Goodall, Alouani-Bibi, & Blundell, 2011) and bright X-ray emission from the supposed termination region (Brinkmann, Aschenbach, & Kawai, 1996).…”
Section: Introductionsupporting
confidence: 82%
“…2 of Roberts et al 2010), except may be the predicted 10% deceleration and twist (the shift of the precession phase by ∼ −0.1) in the innermost ∼ 0. 5 (Panferov 2014; see also Stirling et al 2004). At larger distances the jets become unobservable, possibly because of weakening of the interaction of the jet with the ambient medium.…”
Section: Introductionmentioning
confidence: 98%
“…At larger distances the jets become unobservable, possibly because of weakening of the interaction of the jet with the ambient medium. The jet there would 1 1 = 0.67 · 10 17 cm at the observer distance of D = 4.5 kpc, accepted hereinafter (Stirling et al 2002;Panferov 2010;Marshall et al 2013; see also Lockman et al 2007, andPanferov 2014 for discussion on the distance); data from the literature are compiled to this distance.…”
Section: Introductionmentioning
confidence: 99%