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Dust in Dwarf Galaxies

Dust in Dwarf Galaxies. HERITAGE ( Meixner et al.). Adam Leroy National Radio Astronomy Observatory. Dust in Dwarf Galaxies. HERITAGE ( Meixner et al.). Adam Leroy National Radio Astronomy Observatory. Dust in Dwarf Galaxies. SAGE ( Meixner + `06).

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Dust in Dwarf Galaxies

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  1. Dust in Dwarf Galaxies HERITAGE (Meixner et al.) Adam Leroy National Radio Astronomy Observatory

  2. Dust in Dwarf Galaxies HERITAGE (Meixner et al.) Adam Leroy National Radio Astronomy Observatory

  3. Dust in Dwarf Galaxies SAGE (Meixner+ `06) Based on workby many of the folks here…

  4. Dust in Dwarf Galaxies is … Less abundant than in spiral galaxies… … even more than you expect given the metallicity (?) The dust that is present is deficient in PAHs… … rich in small grains (and/or hotter) … … and exhibits a mysterious long-wavelength excess. This dust is mixed with gas, making it an ISM tracer… … especially useful for hard-to-see molecular gas. And dust appears to help regulate star formation… … influencing the balance of H2-and-HI. D/G SED ISM SFR

  5. D/G How Much Dust in Dwarf Galaxies? Dust-to-Gas RatioRatio of dust mass to total gas mass in the ISM. Relation to Metallicity? Metallicity – ratio of heavy elements to gas mass. Significant fraction of heavy elements in dust in MW (Si, Mg, Fe; most C). Same in dwarfs? Expect roughly linear relation… SNR Shocks Winds PNe, Old *s SN Accretion in clouds

  6. D/G Current Ensemble of Measurements Galametz, madden, et al. ’11 : D/G in dwarf irregulars declines faster than metals … following Lisenfeld & Ferrara `98, Draine+ `07, etc. … much more limited if only sub-mm observations used Dust-to-Gas Mass Ratio Linear Metallicity (12 + log O/H) Points:whole galaxies from wide-net literature trawl

  7. D/G Semi-Resolved: Dust-Poor Envelopes? Draine et al. ‘07: Aperture definition strongly affects D/G in SINGS dwarfs. Dust-to-Gas Mass Ratio Metallicity (12 + log O/H) Points:whole SINGS galaxies but dwarfs treated with varying aperture

  8. D/G Dust-Poor Envelopes? Only over IR Region DGR consistent with metallicity trend. Draine et al. ‘07: Aperture definition strongly affects D/G in SINGS dwarfs. Dust-to-Gas Mass Ratio Over the Whole Galaxy D/G lower than expected given a simple trend with metallicity Metallicity (12 + log O/H) Points:whole SINGS galaxies but dwarfs treated with varying aperture

  9. D/G But it Does Break… Eventually Herrera-Camus et al. (2012): I Zw 18 upper limit rules out linear D/G vs. z Dust-to-Gas Mass Ratio Metallicity (12 + log O/H) Points: whole SINGS galaxies + I Zw 18

  10. D/G But it Does Break… Eventually Fisher, Bolatto et al. (in prep.):Herschel constrains I Zw 18 SED to be very hot  low mass Points:SED of the very low-metallicity BCD I Zw 18 (courtesy D. Fisher)

  11. Dust in Dwarf Galaxies is … Less abundant than in spiral galaxies… … even more than you expect given the metallicity (?) D/G

  12. SED Dust Spectral Energy Distribution Emergent Energy (νFν) Wavelength (μm) Illustration:DustEM Model from Compiègne+ `11

  13. SED Dust in Dwarf Galaxies PAH Emission Out of equilibrium emission from small, carbonaceous grains. Emission in bands from 1 to 20 μm. Large collecting area, minor mass fraction. Emergent Energy (νFν) Wavelength (μm) Illustration:DustEM Model from Compiègne+ `11

  14. SED Dust Spectral Energy Distribution Small Grain Emission Emission from small dust grains out of equilibrium with the ISRF (stochastic heating). Contribute from 10 - 100 μm. Emergent Energy (νFν) Wavelength (μm) Illustration:DustEM Model from Compiègne+ `11

  15. SED Dust Spectral Energy Distribution Emergent Energy (νFν) Large Grain Emission In equilibrium with the interstellar radiation field. Holds most dust mass, dominates above 100 μm. Wavelength (μm) Illustration:DustEM Model from Compiègne+ `11

  16. SED PAH Features vs. Metallicity Engelbracht+ `05, `08; Madden `06: PAH emission systematically declines with metallicity. Metallicity Flux (Fν) [Jy] Wavelength (μm) Spectra: IRS spectra of many galaxies binned and stacked by metallicity.

  17. SED PAH Emission vs. Metallicity Engelbracht+ `05, `08: (Broadband) PAH strength drops around 12+log O/H = 8.2 Metallicity (12 + log O/H) 8-to-24 μm Ratio (roughly tracing PAH strength) Each point:one galaxy

  18. SED Resolving Suppression of PAHs Sandstrom+ `10: PAHs coincident with CO emission, shielding. 3σ CO Emission(well shielded) Map: Local PAH mass fraction (qPAH) in the Small MagellanicCloud, Contour:NANTEN CO

  19. SED “Bluer” IR-Colors Bernard+ `08: (M31)  Milky Way  LMC  SMC progressively bluer far-IR color. Emergent Energy (νFν) Wavelength (μm) Spectra: SEDs of Milky Way, LMC, SMC

  20. SED “Bluer” IR Colors Engelbracht+ `05: 70/160 color correlates with metallicity. Temperature? Smaller grains? 70-to-160 μm Ratio (Temperature or VSG Contribution) Metallicity (12 + log O/H) Points: Individual galaxies

  21. SED Long Wavelength Emission Galliano+ `03,`05, Galametz `09: mm emission from dwarfs higher than expected for β=2. … Planck Collaboration `11 … these extend to longer wavelengths.in the SMC NGC 1569 SMC Planck Collaboration `11 Wavelength (μm)

  22. SED Long Wavelength Emission Galliano+ `03,`05, Galametz `09: mm emission from dwarfs higher than expected for β=2. … Planck Collaboration `11 … these extend to longer wavelengths.in the SMC NGC 1569 SMC Planck Collaboration `11 Wavelength (μm)

  23. SED Long Wavelength Emission Galliano+ `11: Large Magellanic Cloud … sub-mm excess not correlated with H2 Excess Emission Above Standard Fit to SED in SPIRE 500 μm Band H2 Surface Density HI Surface Density Contours: Data distribution for excess measured line of sight by line of sight in the LMC

  24. Dust in Dwarf Galaxies is … The dust that is present is deficient in PAHs… … rich in small grains (and/or hotter) … … and exhibits a mysterious long-wavelength excess. SED

  25. ISM Dust as an ISM Tracer Heritage, Sage, Sage-SMC: Dust maps are ISM maps…

  26. ISM Dust as an ISM Tracer Planck Collaboration+ `11, Leroy+ `09: Correlation of dust emission, H in MW, SMC Milky Way Fit Optical Depth at 160 μm Sub-mm Emission at 550 GHz SMC Hydrogen Column HI Column Data: IR or sub-mm emission vs. gas column for individual lines of sight

  27. ISM Dust as an ISM Tracer • Dust traces the total (HI + H2) gas column • Estimate dust from IR emission, measure HI • Get gas-to-dust ratio by comparison with HI H2 = (dust× GDR)- HI

  28. ISM Dust as an ISM Tracer Dame+ `01: Works to match CO distribution in Milky Way Observed CO H2 from IRAS Dust Emission Comparison in Profile

  29. ISM Dust as an ISM Tracer Leroy+ `09: Reveals similar structure to CO mapping on small scales (10 pc) in SMC. CO emission H2 from Dust Maps: CO (left) and H2 estimated from IR emission (right) in the SMC star-forming complex N83/N84

  30. ISM Dust as an ISM Tracer Bolatto+ `11, Leroy+ `07: Combine IR imaging, HI to infer H2 distribution in the SMC IR Opacity (Spitzer) Atomic Gas (21-cm) Molecular Gas H2 = (dust× GDR)- HI

  31. ISM Dust as an ISM Tracer Leroy+ `11: Conversion factor rises sharply at low metallicity. Dust a good alternative… CO-to-H2 Conversion Factor Metallicity (12+log O/H) Points: Dust-driven solutions for the conversion factor in parts of Local Group galaxies

  32. Dust in Dwarf Galaxies is … This dust is mixed with gas, making it an ISM tracer… … especially useful for hard-to-see molecular gas. ISM

  33. SFR Dust asa Star Formation Regulator Schruba+ `11: Correlation of star formation with molecular and atomic gas Atomic Gas (21-cm) Molecular Gas (CO 2-1) Points: Rings (azimuthal averages) in 30 disk galaxies

  34. SFR Dust asa Star Formation Regulator Leroy+Heracles/Kingfish (in prep.): Molecular to atomic ratio follows gas surface density. Molecular to Atomic Gas Ratio Points: kpc-resolution lines of sight in 22 disk galaxies

  35. SFR Dust asa Star Formation Regulator Leroy+Heracles/Kingfish (in prep.): Molecular to atomic ratio follows gas surface density. Molecular to Atomic Gas Ratio Points: kpc-resolution lines of sight in 22 disk galaxies

  36. SFR Dust asa Star Formation Regulator Leroy+Heracles/Kingfish (in prep.): Molecular to atomic ratio follows gas surface density. Molecular to Atomic Gas RatioDivided by Avg. Ratio at that Surface Density Points: kpc-resolution lines of sight in 22 disk galaxies

  37. SFR Dust asa Star Formation Regulator Leroy+Heracles/Kingfish (in prep.): Molecular to atomic ratio follows gas surface density. Molecular to Atomic Gas RatioDivided by Avg. Ratio at that Surface Density Points: kpc-resolution lines of sight in 22 disk galaxies

  38. Dust in Dwarf Galaxies is … And dust appears to help regulate star formation… … influencing the balance of H2-and-HI. SFR

  39. Dust in Dwarf Galaxies is … Less abundant than in spiral galaxies… … even more than you expect given the metallicity (?) The dust that is present is deficient in PAHs… … rich in small grains (and/or hotter) … … and exhibits a mysterious long-wavelength excess. This dust is mixed with gas, making it an ISM tracer… … especially useful for hard-to-see molecular gas. And dust appears to help regulate star formation… … influencing the balance of H2-and-HI. D/G SED ISM SFR

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