Xray observations of high redshift radio galaxies - PowerPoint PPT Presentation

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Xray observations of high redshift radio galaxies

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Xray sources: 15 type-I AGN, 1 type-II, 1 star. Two confirmed at z = 2.2, Four others likely ... 1138-262: rich in Xray-loud AGN? (Pentericci et al. 2002) ... – PowerPoint PPT presentation

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Title: Xray observations of high redshift radio galaxies


1
Xray observations of high redshift radio galaxies
Thermal emission a. Cluster Atmospheres Be
acons to high z (proto-)clusters,
Constrain Omega_M b. Hydrodynamic
interaction of radio source and ISM/ICM
Cavities, Bow shocks, constrain source
dynamics, probe pre-existing ICM Non-t
hermal emission a. Synchrotron emission co
nstrain high gamma_e and particle
acceleration mechanisms
b. Inverse Compton emission constrain
magnetic fields, low gamma_e AGN emis
sion constrain emission processes (accretion
disk, core-jet, scattering), absorption col
umns, constrain L_opt, identify cluster member
AGN (type-II AGN?)
2
Cygnus A (Wilson, Smith, Arnaud, Young)
200 kpc
L_X L_R L_O 1e45 erg/s
M_grav 2e14 M_sun, M_gas 1e13 M_sun

3
Hydrodynamics of a powerful radio jet (Clarke et
al 1999)
Radio
Xray
4
Cygnus A hydrodynamics
Shocked ICM n0.01, T7e7, P 1e-10 (cgs)
Radio lobe (minE) B 30 uG, P 2e-11 (cgs)
Departure from minimum energy?
5
Caution what you CAN see is what you get
Clarke et al 1996
6
IC emission from radio hot spots and lobes
Sync
B_SSC 150 uG B_minE 250 uG
SSC
7
Synchrotron vs. IC (CMB) losses vs. redshift
8
Radio quiet, IC loud jets at very high z?
z5.99 Schwartz 2002
T_CMB 2.7(1z) nu_CMB 1.6e11(1z)
Gamma_e (1 keV obs) 1000 (independent of
z!) t_e 9.4e5yrs U_CMB aT4 off-sets
distance losses Gamma_e (5 GHz obs) 7000 t_
e 2.5e6 yrs
9
Synchrotron jets 3C 273 (Marshall et al. 2002)
Merlin HST
Chandra/HST
gamma 2e7 t_e 70 yrs
10
Cygnus A nucleus AGN emission and absorption
nucleus L_2-10keV 4e44 erg/s
alpha -0.8, N(HI) 2e23 cm-2
scattered (electron) L_2-10keV 4e42 erg/s
11
Examples at z 0.5
3C263
3C330
3C351
3C295 Harris et al. 2002
Hardcastle et al. 2002
12
Xray observations of z 2 radio galaxies
1138-262 z2.2
0236-254 z2.0
3c294 z1.8
0902343 z3.4
4
13
Massive, virialized clusters at high redshift?
1138-262, 0902343, 2036-254 No
Beta 2.5 R_c 12
L_x (cluster) A)

14
3C 294 Yes? (Fabian etal. 2001)
L_x (cluster) 5e44 erg/s M_virial 1e14 M_sun
(T_x 3keV)
Omega_M
3
5
9kev
15
1138-262 rich in Xray-loud AGN? (Pentericci et
al. 2002)
Xray sources 15 type-I AGN, 1 type-II, 1 star
Two confirmed at z 2.2, Four others likely
Overdensity 2x field AGN in (proto-)
cluster?
16
Xray spectra of high z radio galaxy AGN
1138-262 3C294
0902343
3e45 8e22 -1.1
1e45 7e23 -2
L_2-10keV 4e45 erg/s N(HI) 3e22 cm-2 Gamma
-1.8
N(HI) 1e23 A_V 60
17
AGN Radio-Xray-Optical correlations
Brinkmann et al. 1997
Obey L_x L_R,core for steep spectrum quasars
L_Q (2036-254) 1e46 erg/s L_Q (1138-262)
1e47 erg/s
18
Radio-Xray alignment effect
1138-262 z2.2
0236-254 z2.0
3c294 z1.8
4
19
3C294 West-Barthel/Arnaud effect
Giant elliptical galaxies form from filamentary
mergers Radio jets oriented along the major axis
of matter distribution are more luminous (ie.
higher conversion efficiency) (?)
Dubinski 1998
20
2036-254 Brunetti mechanismIC of AGN
radiation field
-0.92 but opposing X/R gradients
argue against synchrotron and IC_CMB
Consistent with IC_Q B_IC 25 uG vs.
B_minE 75 uG Counter-lobe brighter back-scatte
ring time delay
21
1138-262 Multiple (all?) mechanisms
Radio-Xray
22
Optical-Xray
23
Ly alpha Xray
24
Ly alpha - Radio
25
Soft
Medium
Hard
26
1138-262 Multiple Mechanisms
Not
Scattering required core luminosity too high
wrong spectrum Synchrotron requires spectral fla
ttening and non-detected in optical
Could be
Two AGN IC_Q in jet B_IC 30 uG (but offsets
in outer source not IC?)
Hot Gas shock-heated, I(proto-)CM
n_e 0.05 cm-2 M_gas 2.5e12
M_sun P_x 8e-10 P_minE 6e-10
P_line 1e-9 Xrays reveal the pervasive me
dium confining radio source and
line clouds?
27
Rees model for proto-Giant
elliptical 1. Multiphase medium clouds/filaments
at temperatures ranging from low ff clouds at
1e4 K to high ff, virialized gas at 1e6-7 K.
2. Passage of Jet shock High density clouds (
few cm-2) are induced to form stars in higher
pressure environment Medium density regions (0.5
cm-2) are shocked but cool on timescales
1e7yrs, giving rise to Ly alpha emission
Low density regions (
to X-ray emitting temperatures as seen by CHANDRA
28
Multiphase cloudy medium 1e4 1e7K
A. Ambient medium into which radio source
expands changes significantly with
redshift. B. Overdensity of galaxies will evol
ve into cluster, but lack of X-ray cluster atmos
phere not dynamically relaxed
proto-cluster
29
Xray observations of high redshift radio galaxies
Thermal emission a. Cluster Atmospheres Be
acons to high z (proto-)clusters,
Constrain Omega_matter Not seen
PROTO-clusters? b. Hydrodynamic interaction o
f radio source and ISM/ICM Cavities, Bow
shocks, constrain source dynamics, probe
pre-existing ICM Shocked gas confining
RS line clouds Non-thermal emission a.
Synchrotron emission constrain high gamma_e and
particle acceleration mechanisms b.
Inverse Compton emission constrain magnetic
fields, low gamma_e Brunetti mechanis
m at work L_Q1e46 AGN emission constrain e
mission processes, absorption columns, constrain
L_opt Large N(HI) (but not Compton thick),
consistent with steep spectrum Quasars L_Q1e46
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