Interstellar Dust and Extinction - Astrophysics

Transcription

Interstellar Dust and Extinction
Michael Colling
University of Oxford, Astrophysics
November 12, 2007
Extinction
Spectral Features
Emission
Scattering
Polarization
Grain Models & Evolution
Conclusions
Outline
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
What and Why?
I
‘Dust’ covers a range of compound molecules with widely
varying absorption, emission and scattering properties.
I
Grain sizes range from 5×10−4 - 0.5µm and composes 1% by
mass of the Interstellar Medium (ISM).
I
Dust absorbs optical and ultra-violet (UV) light, scatters
optical - x-rays and emits in the infra-red (IR).
I
IR emission provides 30% of the flux of a typical galaxy (e.g.
Milky Way). Two-thirds of this is in the far infra-red (FIR)
(λ ≥50µm) from cold, larger grains ( 20K, ≥0.01µm) near
early-type stars. The remaining third is from smaller grains
(≤0.005µm) cooling from photo-absorption.
I
Large dust grains provide the most efficient source of cooling
in the ISM and provide UV-free surfaces for chemical
reactions to occur, including formation of the H2 molecule.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Definitions
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Extinction Definitions
Extinction = Absorption + Scattering
I
Extinction is commonly expressed as
A(λ)
A(V )
or
E (λ−V )
E (B−V )
where
F0
A(λ) = 2.5log( Fλλ )
E (λ − V ) = A(λ) − A(V )
I
An extinction law is a measure of the variation of extinction
with wavelength. These are usually defined by the parameter
Rv ≡
AV
E (B−V )
=
Av
(AB −AV )
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Extinction Law
Rv ≡
AV
E (B−V )
=
Av
(AB −AV )
For large grains Rv → ∞
For Rayleigh scattering with Aλ ∝ λ−4 RV ≈ 1.2
I
In the galactic diffuse ISM and Large Magellanic Cloud
RV ≈ 3.1 varying along sightlines from 2.1 to 5.8
I
In the Small Magellanic Cloud RV ≈ 3.2, but without the
2175Å feature.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Extinction Law
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Extinction Laws around the Universe (Czerny 2006)
(Vote for the stupidest one!)
I
Milky Way: RV ≈ 3.1, prominent 2175Å feature
I
SMC: RV ≈ 3.2, no 2175Å feature
I
Starburst Galaxies, lensing galaxies: SMC-like, but less steep at
shorter λ
I
Quasars: RV from 0.7 to 5.5 where found, some with 2175Å
feature. Some show flatter and greyer curves than MW and SMC,
but may be resolved to SMC accounting for bias. The lack of a
2175Å feature is associated with: low metallicity, strong radiation
fields and/or large densities.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Measuring Extinctions
I
The Pair Method: The most reliable method of measuring
extinction. Spectrophotometry of two stars of the same
spectral class are compared: one with negligible foreground
dust and the other heavily reddened. This method assumes
that dust extinction goes to zero at long wavelengths. This
method is also used for galaxies that overlap other galaxies
and gravitationally lensed QSOs.
I
Multi-band photometry: Based on fitting a known extinction
curve, or fitting a theoretical one, to photometric data.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Tracing the Dust
Moving from optical to near-IR in the DR21 Starforming region
(Spitzer)
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
2175 Å Feature and Diffuse Interstellar Bands
I
I
2175Å feature: A broad absorption feature associated with
aromatic (no long-range order) Carbon, particularly some form
of graphite, from oscillator-strength calculations. Seen with
varying strength in this galaxy and others, but not observed in
the Small Magellanic Cloud or in circumnuclear dust around
AGN.
Diffuse Interstellar Bands: Small finely-structured absorptions
mainly seen in the optical. Sometimes correlated with the
2175Å UV band (Desert et al. 2005). 5797 and 6614Å
bands show structure consistent with rotational bands in
molcules (Kerr et al 1996, 1998). Possibly of PAH
compostion.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
2175 Å Feature and Diffuse Interstellar Bands
DIBs (Kerr et al. 1998) and Extinction Curves (Fitzpatrick 1999)
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Silicate and Hydrocarbon Absorption
I
Silicates: At 9.7µm and 18µm. 9.7µm feature associated with
the Si-O stretching mode, while 18µm feature associated with
O-Si-O bending mode.
I
3.4µm Feature: Present in diffuse atomic regions and linked
with the C-H stretching mode in aliphatic (chain-like)
hydrocarbons. Exhibits substantial substructure allowing
‘carbon-soups’ to be tested in the laboratory.
I
Ice Features: In dense molecular clouds a 3.1µm feature is
observed, due to O-H stretching in solid H2 O. In the Taurus
dark cloud complex, this was measured to be present only in
regions where AV ≥ 3.3mag. There is also evidence for CO2 ,
NH3 , CO, CH3 OH, CH4 and others.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Silicate Absorption
The 9.7µm silicate absorption in two galaxies (Roche 2007)
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
3.4µm Absorption
The 3.4µm hydrocarbon absorption in two galaxies (Mason 2004)
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Polycyclic Aromatic Hydrocarbons (PAHs)
PAH observations are concentrated in 5 emission features:
I
C-H stretching mode at 3.3µm
I
C-C stretching mode at 6.2µm
I
C-C stretching mode at 7.7µm
I
C-H in-plane bending mode at 8.6µm
I
C-H out-of-plane bending mode at: 11.3µm (no adjacent H),
12.0µm (2 contiguous H), 12.7µm (3 H), 13.55µm (4 H)
PAHs are observed to be particularly strong in star forming regions:
hence the now often-used correlation between PAH activity and
star formation.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Polycyclic Aromatic Hydrocarbons (PAHs)
The PAH bands in the Mid-IR (Mason 2007)
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Dust Emission
A movie comparing optical and IR emission in the Carina Nebula
(around Eta Carinae) (Spitzer)
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Dust Emission
I
Infra-red emission: Except for the highest densities, dust
heating is by starlight photons of various energies. For large
grains with radii ≥200 Å this heating can be approximated as
steady and the cooling a steady thermal process. For smaller
grains the heating can be erratic and highly quantized
excitation and emission. These ‘nanoparticles’ account for
35% of starlight re-emission. (Witt 1999)
I
Extended Red Emission (ERE): also known as Unidentified
Infra-red Bands (UIBs). These carry at least 10% of
optical/UV photons. The ERE carrier must be a very efficient
photoluminescent. The best candidates are HACs
(Hydrogenated Amorphous Carbon) and PAHs, but both have
problems (Witt 1999).
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Scattering
I
Optical and UV: dependent on the grain albedo and the
scattering assymetry factor g ≡cosθ. Appears to be a
decrease in the albedo from optical to UV; a rise in g from
optical to UV; consistent values with carbonaceous/silicate
grain models (Witt et al 1992)
I
X-Ray: scattered through small scattering angles causing a
‘halo’ effect around x-ray sources. The observation of this
effect allows tight constraints to be place on grain models:
grain sizes and morphology.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Polarization
I
In optical and UV the ‘Serkowski law’ empirically gives the
degree of polarization due to aligned dust grains (Serkowski
1973,1975):
p(λ) = pmax exp(−K (ln(λ/λmax ))2 )
where λmax ≈5500Å and K ≈ 1.
I
In IR one can observe the polarization in the absorption and
emission bands for preferential alignments. This can constrain
grain models that require co-existing populations of different
grain types, or silicate/hydrocarbon grains composites.
Evidence so far indicates that the polarization of the 9.7µm
feature does not correlate with that of the 3.4µm feature
(Mason 2007).
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
What is the dust made of?
An artist’s impression of a dusty disc around a young star (Spitzer)
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Candidate Grain Materials
I
Silicates: at least 95% amorphous (Li & Draine 2002),
expected to be predominantly Mg or Fe compounds from
cosmic abundances. Where crystalline silicates are found, they
are Mg rich (Tielens 1998).
I
Carbonaceous Materials: including diamond, graphite,
amorphous/glassy carbon, hydrogenated amorphous carbon,
PAH, aliphatic hydrocarbons.
I
SiC: Found in meteorites and an 11.3µm feature in carbon
stars. Line extinctions suggest that less than 5% Si in dust is
in this form.
I
Carbonates: Found in dusty discs, but estimated to contribute
less than 1% of dust mass.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Grain Models
A comprehensive grain model does not exist that can fully describe
dust grains and their properties.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Grain Models
A model of grain sizes and populations (Draine 2003)
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Grain Evolution?
I
Stellar Outflows: Dust is observed in stellar outflows and
some dust clearly must condense from gas in the stellar
envelope. Similarly this occurs around AGN and other
gas-shock phenomena.
I
ISM Processing: Studies of the destruction of dust grains
suggest a ‘residence time’ of order 3×108 yr. Taking the mass
of the ISM as 59 M and a star formation rate of 5M yr−1
then the mean residence time of a metal atom in the ISM is
109 yr. Only a fraction (0.2) of the Si atoms in the ISM would
still be in the original dust particle in which they left the star.
However, over 90% of Si is missing from the gas phase: there
must be reprocessing in the ISM.
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Dust: You can’t ignore it!
An artist’s impression of a heavily obscured galaxy, moving from
optical to the IR (Spitzer)
Michael Colling
Extinction
Spectral Features
Emission
Scattering
Polarization
Conclusions
Conclusions
I
Dust causes extinction in the optical and UV bands which can
be modelled by a standard curve for which one only needs to
AV
measure/estimate RV = E (B−V
) to fit. RV = 3.1, on average,
in the Milky Way.
I
The composition of the dust is estimated through absorption
and emission features and atomic calculations. This can then
tell us about the region the dust is in. The best candidates
are silicates and carbonaceous materials. Dust is a catalyst for
interstellar chemistry.
I
Dust models need to reproduce the UV, optical and IR
absorptions, the polarizations, scattering coefficients, IR and
PAH emissions and fit elemental abundances to be taken
seriously.
Michael Colling

Interstellar Dust and Extinction - Astrophysics

Transcription

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