MOLECULAR GAS IN THE CORES OF AGN
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Transcript of MOLECULAR GAS IN THE CORES OF AGN
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MOLECULAR GAS IN THE CORES OF AGN
Violette Impellizzeri (NRAO)Alan Roy (MPIfR), Christian Henkel (MPIfR)
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The unified scheme of AGN Diversity of AGN classes explained by a single unified scheme :
The nuclear activity is powered by a supermassive black hole ( 10∼ 6–1010 M⊙) and its accretion disk.
This central engine is surrounded by dusty clouds, which are individually optically thick, in a toroidal structure (Krolik & Begelman 1988). Populated by molecular clouds accreted from the galaxy.
Observed diversity is the result of viewing this axisymmetric geometry from different angles.
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The unified scheme of AGN
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The torus: size To determine an actual size one must rely on the torus emission.
Pier & Krolik (1992) approximate the density distribution with a uniform one : outer radius R 5 pc – 10 pc∼ .
Pier & Krolik (1993) : later speculated that compact structure might be embedded in a much larger, and more diffuse, torus with R 30 pc –100 pc∼ .
Granato and Danese (1994) elaborate toroidal geometries, concluded that the torus must have an outer radius R ~ 300 pc – 1000 pc.
Granato et al (1997) settled on hundreds of pc. Subsequently, R > 100 pc became common lore.
High-resolution IR observations brought unambiguous evidence in support of compact torus dimensions. VLTI interferometry shows that the 10 μm flux comes from a hot (T > 800 K) central region of ∼ 1 pc and its cooler (T 320 K) surrounding within ∼ R 2 pc ∼and 3 pc (for NGC 1068; Jaffe et. al 2004).
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The dusty torus: MIR interferometry
T1 = 334 K
T2 = 298 K
Tristram et al. 2007
T1
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The dusty torus: MIR interferometry T1 = 334 K
T2 = 298 K
Tristram et al. 2007
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The torus : molecularSy1
Sy2
NH 1022 cm-2 ; OH opacities << 1
NH 1024 cm-2 ; OH opacities > 1
Molecular abundances in tori: N(OH)/N(HI) ≤ 10-3
(Krolik & Lepp 1989)
Dusty AGN torus is molecular gas rich
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OH surveys Expect to observe molecular absorption against the compact, flat spectrum radio
cores of NLRs.
Not only confirm the existence of a torus, but also derive valuable physical and kinematical information.
OH surveys at 1.6 GHz • Schmelz et al. 1986, • Staveley-Smith et al. 1992, • Baan et al. 1992 • ... (sensitivities of few percent)CO, HCN and HNC searches • Drinkwater et al. 1997 Surprisingly few detections!
OH abundance lower than predicted ? No torus ?
Observed ~ 300 galaxies Low detection rates (absorption towards two Seyferts maser emission in five).
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No CO absorption in Cygnus A Of all AGN Cygnus A is expected to have a molecular torus
NLR
Large X-ray absorbing column (1023.5 cm-2)
Search for CO (1-0) absorption yielded non detection!
Search for OH (1.6 GHz) non detection
H2CO non detection
HI detected (Coway & Blanco 1995)
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Radiative excitation I Gas in a hot (5000 -10000 K) mainly atomic phase.
Radiative excitation of CO, OH and NH3 due to the central radio source causes the non detection of molecular absorption (Maloney, Begelman & Rees 1994).
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Radiative excitation I Gas in a hot (5000 -10000 K) mainly atomic phase.
Radiative excitation of CO, OH and NH3 due to the central radio source causes the non detection of molecular absorption (Maloney, Begelman & Rees 1994).
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Radiative excitation effects Maloney, Begelman, & Rees (1994) postulate that lack of CO
absorption is due to radiative excitation by non-thermal radio source: High Tex depletes lower rotational levels, decreasing optical depth is OH, too, radiatively excited ?For torus located 10 pc from AGN:
• opacity in 1.6 GHz transition suppressed by factor 103
• opacity in 6.0 GHz transition suppressed by factor 102
• opacity in 13.4 GHz transition will increase slightly by factor 2. Black (1998) Thus, absorption will strongly depend on transition one chooses to observe. Have we been looking at the right transitions ?
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A new survey for OH Search for highly excited rotational states of OH at 6.035 GHz & 6.031 GHz, 4.750
GHz and 13.4 GHz.The sample: 31 Seyfert 2 galaxies High X-ray absorbing columns (> 1022 cm-2 ) Continuum flux density at 6 GHz > 50 mJy HPBLEffelsberg observations:• 3-10 hours per source at 4.7 GHz and 6.0 GHz, PSW• Velocity coverage 2000 km/s (4 km/s per channel)• Sensitivity 3.5 mJy (5 σ) = line opacity of 0.002 to 0.07
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Effelsberg Spectra 6.0 GHz
Best targets due to high X-ray columns and high background continuum at 6.0 GHz.
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Effelsberg Spectra 6.0 GHz
Too strong continuum - Large standing wave ripple!5 new detections - detection rate 18 %
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Effelsberg Spectra 6.0 GHz
Lets look at NGC 3079 & NGC 5793.
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NGC 3079 NGC 5793
•Width ~ 800 km s-1
•Line opacity τ ~ 0.055•4.7 GHz non-detection•1.6 GHz abs (Baan et al. 1995)
Tex = 30 K
NOH = 1.5 1018 cm-2
from X-rays: NH = 1.0 1025 cm-2
•Width ~ up to 1000 km s-1
•Line opacity τ ~ 0.036•4.7 GHz non-detection•1.6 GHz abs (Hagiwara et al. 2000)
Tex = 67 K
NOH = 2.2 1017 cm-2
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Conclusions from OH survey A survey for 6.0 GHz and 4.7 GHz with Effelsberg found highly excited,
broad absorption lines in 5 out of 28 sources, i.e. 18%.
Line widths are 100s-1000 km/s (close to nuclear region?).
Selection criteria improved detection rate c.f. other OH surveys (< 7%).
No new detections at 6.0 GHz were made where there was no previous OH absorption/emission at 1.6 GHz.
Results do not support radiative excitation models alone to explain the lack of detections.
Still some sources with high column density didn’t show absorption.
But still the non detections must be explained !!
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Some open questions Bimodal distribution of absorptions –> very compact clouds ?
Broad lines in infall/outflow ? Not a simple rotating torus ?
X-ray absorber may be non-molecular in most galaxies ??
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VLBI Observations VLBA observations carried out with interferometric observations to
detect OH at 13.4 GHz towards the core of NGC 1052 and Cygnus A.
=> 0.9 mas beamObserving time:
NGC 1052 – 7 hoursCygnus A – 8 hours
Bandwidth 16 MHz (256 channels) per IF.
Velocity coverage ~ 560 km/s.
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NGC 1052 Nearby radio galaxy classified as LINER (z=0.0049)
Hosts well-defined double-sided radio jet w/ P.A. 650
Jet extends up to kpc scale, angle of jet axis is > 760.
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NGC 1052 Nearby radio galaxy classified as LINER (z=0.0049)
Hosts well-defined double-sided radio jet w/ P.A. 650
Jet extends up to kpc scale, angle of jet axis is > 760.
Multi-frequency VLBI observations have revealed the presence of a dense circumnuclear structure.
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NGC 1052 Nearby radio galaxy classified as LINER (z=0.0049)
Hosts well-defined double-sided radio jet w/ P.A. 650
Jet extends up to kpc scale, angle of jet axis is > 760.
Multi-frequency VLBI observations have revealed the presence of a dense circumnuclear structure.
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NGC 1052 Nearby radio galaxy classified as LINER (z=0.0049).
Hosts well-defined double-sided radio jet w/ P.A. 650.
Jet extends up to kpc scale, angle of jet axis is > 760.
Multi-frequency VLBI observations have revealed the presence of a dense circumnuclear structure.
Plasma condensation covers 0.1 pc and 0.7 pc of approaching and receding jet (Kameno et al. 2001).
X-ray column is 1022 – 1023 cm-2 (e.g. Kadler et al. 2004).
H2O megamasers found towards the centre redshifted by 50-350 km/s wrt systemic (e.g. Braatz et al. 2003).
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NGC 1052
Sawada-Satoh et al. 2008
H2O detected where free-free opacity large.
Other lines have been detected :
HI, OH, HCO+, HCN and CO…
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NGC 1052
Sawada-Satoh et al. 2008Vermeulen et al. 2003
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NCG 1052 – VLBA 13.4 GHZ
Broad Width:FWHM ≈ 200 km/s
Optical depth(counter jet)
τOH ≈ 0.264
Obscuration in the inner jet region (< o.3 pc), coincident with free-free absorption.
Vsys
0.2 pc
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NGC 1052 – where is absorption located?
Optical depth map
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NGC 1052 – where is absorption located?
Optical depth map
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NCG 1052 – VLBA 13.4 GHZ
Receding jet
Approaching jet
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Are we seeing the torus in NGC 1052?
Approaching jet
Receding jet
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Fitting into the picture
Sawada-Satoh et al. 2008
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Fitting into the picture
Sawada-Satoh et al. 2008
OH
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Cygnus A
Continuum peak flux 453 mJy per beam
Optical depth (core) τOH ≈ 0.12 Absorbing gas is diffuse around the inner jets.
Profile strongest over the entire continuum.
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Cygnus A
Continuum peak flux 453 mJy per beam
Optical depth (core) τOH ≈ 0.12 Absorbing gas is diffuse around the inner jets.
Profile strongest over the entire continuum.
Conway & Blanco 1995
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Conclusions from VLBA observations
13.4 GHz OH was detected for the first time in the core of an AGN (NGC 1052 and Cygnus A).
Evidence for molecular gas in the region we would expect to see a torus.
In Cygnus A, if real the detection is consistent with radiative excitation models proposed for this source.
In NGC 1052, redshifted OH gas cloud detected toward the counterjet.
Part of rotating torus/infalling material ?
Detection consistent with previous H2O observations.
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Future outlook Detections will strongly depend on which transition one chooses to
observe! Future surveys for the molecular component of AGN should include the 13.441 GHz
and 13.434 GHz lines of OH. New instruments like the VLBI, EVLA, and ALMA (just around the corner) with their
increased sensitivity will hugely contribute to a high resolution, sensitive study of the molecules in AGN:
perhaps a new era also for the Torus?
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Future outlookFor a source at the distance of NGC 1052:
VLBA resolution : 1mas at 13.0 GHz : 0.1 pcEVLA resolution : 4 arcsec at 5.0 GHz : 400 pcALMA resolution: 18mas at 1mm : 2 pc (extended configuration 17 km) ALMA resolution : 0.5 arcsec at 1mm: 50 pc (early science)
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ALMA
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Spiral Galaxy in Ursa MajorDistance: 15 Mpc (50 million light-years)Dimensions: The full image 4.9´( 21 kpc)Sy2 galaxy Nh = 1.6 1022 cm-2
FIR excess: Lfir = 19 109 Lsun
CO (1-0) emission tracing disk (Nh = 1.4 1024 cm-2)Most luminous H2O megamaser known
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