University of Hertfordshire

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  • 904928

    Submitted manuscript, 702 KB, PDF document

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Original languageEnglish
Article number95
JournalThe Astrophysical Journal
Journal publication date20 Oct 2012
Volume758
Issue2
DOIs
Publication statusPublished - 20 Oct 2012

Abstract

We analyze new Chandra observations of the nearest (D = 4 Mpc) Seyfert 2 active galaxy, Circinus, and match them to pre-existing radio, infrared, and optical data to study the kpc-scale emission. The proximity of Circinus allows us to observe in striking detail the structure of the radio lobes, revealing for the first time edge-brightened emission in both X-rays and radio. After considering various other possible scenarios, we show that this extended emission in Circinus is most likely caused by a jet-driven outflow, which is driving shells of strongly shocked gas into the halo of the host galaxy. In this context, we estimate Mach numbers -3.6 and -5.3 for the W and E shells, respectively. We derive temperatures of 0.74 keV and 0.8-1.8 keV for the W and E shells and an expansion velocity of ∼900-950kms . We estimate that the total energy (thermal and kinetic) involved in creating both shells is ∼2 × ∼10 erg, and their age is 10 yr. Comparing these results with those we previously obtained for Centaurus A, NGC3801, and Mrk 6, we show that these parameters scale approximately with the radio power of the parent active galactic nucleus (AGN). The spatial coincidence between the X-ray and edge-brightened radio emission in Circinus resembles the morphology of some supernova remnant shocks. This parallel has been expected for AGNs but has never been observed before. We investigate what underlying mechanisms both types of systems may have in common, arguing that, in Circinus, the edge-brightening in the shells may be accounted for by a B field enhancement caused by shock compression but do not preclude some local particle acceleration. These results can be extrapolated to other low-power systems, particularly those with late-type hosts.

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Copyright American Astronomical Society

ID: 1911478