Post on 15-Jan-2016
description
Emissions from Shells Associated with Dying
Radio Sources
@Workshop on East-Asian Collaboration for the SKA 2011 12/2
Hirotaka Ito YITP, Kyoto University Collabolators
Nozomu Kawakatu Tsukuba University Motoki Kino NAOJ
Shocked Shell
Forward shock
Radio lobe
Jet
Lobe
Shell
Energy dissipation
shell
Shell = shocked ambient gas
Comparable energy is deposited in the lobe and shell
Non-thermal synchrotron emission (S ν∝ -α )
Centausus A
Shell γe ~ 108 (B/10μ G ) -1/2
Chandra
e.g., Fujita+(2007, 2011), Berezhko (2008), Ito+(2011)
X-ray observation of shell
Shocked shells offer sites for particle accelerations
Croston + (2009)
- comparable energy is deposited in the lobe and shell
e.g., Carilli et al. 1998
- prominent radio emission from lobe is confirmed in large number of sources
- no radio emission is detected in shell ( few nearby sources are detected X-ray )
Lobe emission dominated over the shell emissions
- lobe and shell are site of particle acceleration
Shells in dying radio sourcesThe fraction ( ~15-30% ) of young compact radio sources ( R<few kpc ) in the flux-limited catalogues is much larger than that expected from their age (~0.01%)
e.g., Gugliucci + 2005, Kunert-Bajaszewska+2005, 2006, Orienti+2008,2010
Lobe emission fades rapidly (fader)
Emission from sources after the jet injection has ceased
e.g, Reynolds+ 1997, Mocz+2010, Nath 2010
fresh electrons are no longer supplied
electrons are continuously supplied from the bow shock
Shell emission becomes dominant
Shell emissions only show gradual decrease
significant fraction of young sources may be short-lived
Present StudyEvolution of emissions from lobe and shell of dying radio sources
jet
Lobe-dominated
shell-dominated
Fading phase
Jet active phase
・ spherical symmetry Assumptions
Dynamicsthin shell approximation (e. g., Ostriker & McKee 1988)
tj : duration of jet injection
(I) blast wave with continuous energy injection
(II)
blast wave of instant energy (Sedov-Taylor expansion)
・ ambient density profile
Lj : jet power
Non-thermal electrons (shell)
Adiabatic cooling
Synchrotron
Inverse Compton ( IC )
・ cooling
・ injection
Maximum energy
Normalization factor- UV emission (accretion disc)
- CMB
- IR emission (dusty torus)
- NIR emission (host galaxy)
Seed photons
- Radio emission (Lobe) compression of ISM magnetic field
・ cooling
・ injection
Maximum energy
Normalization factor
No emission from core
compression of ISM magnetic field
Adiabatic cooling
Synchrotron
Inverse Compton ( IC )
- CMB
- NIR emission (host galaxy)
Seed photons
- Radio emission (Lobe)
Non-thermal electrons (shell)
・ cooling
・ injection
Maximum energy
Normalization factor
10% of the equipartition value
Non-thermal electrons (lobe)
Adiabatic cooling
Synchrotron
Inverse Compton ( IC )
- UV emission (accretion disc)
- CMB
- IR emission (dusty torus)
- NIR emission (host galaxy)
Seed photons
- Radio emission (Lobe)
・ cooling
・ injection
No injection
Non-thermal electrons (lobe)
No emission from core
Adiabatic cooling
Synchrotron
Inverse Compton ( IC )
- CMB
- NIR emission (host galaxy)
Seed photons
- Radio emission (Lobe)
Evolution of energy distribution of non-thermal electrons
High energy electrons within the lobe depletes due to the absence of injection
t=10^5 yr (R~1.5kpc)
t=5×10^5 yr (R~5kpc)
t=10^6 yr (R~8kpc)
t=10^7 yr (R~30kpc)
Radiative cooling
SHELL LOBE
after the jet injection has ceased emission is dominted by the shell
Evolution of emission spectrum
candidates for unID radio sources
good target for SKA
D=1Gpc
Detectection prospects
Using simple dynamical model, we evaluated the emissions from dying young radio sources
-
Target for SKA
Shell emissions becomes dominant after the jet injection has ceased due to the rapid decrease of lobe emissions
-
Summary
- Emissions from the shell is essential for studying the properties of dying radio sources
- Some of the unidentified radio sources may be attributed by the shell emissions