Upgrade to Pro — share decks privately, control downloads, hide ads and more …

Dusty Thoughts

Karl Gordon
October 26, 2020

Dusty Thoughts

Thoughts on Dust (invited intro talk) for the "The Rise of Metals and Dust in Galaxies through Cosmic Time" meeting held Oct, 2020 (https://metals-dust.sciencesconf.org/)

Karl Gordon

October 26, 2020
Tweet

More Decks by Karl Gordon

Other Decks in Science

Transcript

  1. Dusty Thoughts Metals/Dust Meeting #MetalsDust2020 26 Oct 2020 Karl D.

    Gordon Astronomer STScI [email protected] @karllark2000 karllark@github “Have Dust – Will Study” Image: Messenger, Scott & Sandford, S. & Brownlee, D.. (2006). The Population of Starting Materials Available for Solar System Construction
  2. “The objective of this talk (R0.1) will be to try

    asking the main questions about metals and dust that you would like to be addressed during this conference (given the general program, of course).”
  3. Cautions • Biased by my knowledge/experience • Focused on Dust

    • Dated? (no longer can even scan astrop-ph) • Comments/suggestions/etc always welcome • Questions, slack, email, twitter, ...
  4. Questions • What is dust? • What are the dust

    properties at different z? – Metallicity, redshift, distance in/from a galaxy, ... • What is the origin of dust? – Young stars, evolved stars, ISM, …
  5. Connections • Local ↔ Distant – Local↔ Distant Universe –

    Often proposed, rarely done • Observations ↔ Theory – UV, IR, submm, optical, X-ray, ... – Grain models, Radiative Transfer
  6. Observations • James Webb Space Telescope (JWST) – What can

    we expect for dust? • ALMA & HST • Optical/NIR/MIR ground-based observatories • Archival Observations – IRAS, ISO, Spitzer, Herschel, Akari, Chandra, etc. • What have/will we learn about dust?
  7. Dust versus Metallicity (UV) • Ultraviolet → effects of dust

    strong, 2175 A bump • UV extinction → Local Group – Average varies with metallicity yet full range at single metallicity • UV attenuation → More distant galaxies – Wider range of metallicities – Extinction ↔ Attenuation – What is the full range of observed UV attenuations? – Radiative Transfer needed to interpret
  8. SMC AzV 456 SMC Bar LMC2 LMC General MW Quiescent?

    Processed? Large Range of Extinction Curves UV Slope Gordon et al. (2003, ApJ, 594, 279)
  9. MW has “LMC/SMC” like sightlines Low density sightlines show MC

    dust Same sightlines also show signatures of processing (high Ca/Na line ratios) Clayton et al. (2000, ApJS,129, 147) Valencic et al. (2003, ApJ, 598, 369) HD 204827 shows SMC Bar dust after foreground subtracted HD 204827 SMC Bar
  10. Extinction ↔ Attenuation • Extinction → direct measure of dust

    grains – Hard to measure outside the Local Group (except GRBs?) (with existing facilities) • Attenuation → dust grains + geometry – Geometry = star/dust & ISM structure – Can be measured at many redshifts – Need dust different than Local Group?
  11. Radiative Transfer • Global and Local geometry matters – Global:

    spherical, disk, arms, … – Local: small scale clumpiness • The physics of dust RT restricts the allowed attenuation curves • Need – Grids: explore parameter space (too simple?) – Individual galaxies: detailed studies (too complex?)
  12. Global Geometries Local + Global Geometries Witt, Thronsen, & Capuano

    (1992, ApJ, 393, 611) Witt & Gordon (2000, ApJ, 528, 799) Seon & Draine (2016, ApJ, 833, 201)
  13. Witt & Gordon (2000, ApJ, 528, 799) For an alternative

    explanation with MW dust solution for starbursts, see: Panuzzo et al. (2007, MNRAS, 375, 640) SMC-like dust in Starbursts
  14. Detailed Modeling of M51 De Looze et al. (2014, A&A,

    571, 69) Dust Heating 63% from young stars (< 100 Myr) 37% from old stars (~10 Gyr)
  15. Dust versus Metallicity (IR) • Emission probes dust and illuminating

    sources • Total emission → mass of dust – High redshift/low metallicity → clues to dust formation • Aromatic/PAH features – Probes of carbonaceous dust – Galaxies with different environments (SF, metallicity)
  16. Dust Masses Aniano et al. (2020, ApJ, 889, 150) Data:

    Herschel+Spitzer Lines: Simple Model with dust formation/destruction time scales
  17. Total Dust Mass “Scare” Plot Deriving dust mass from IR

    Emission non-trival Variations with metallicity? Calibration with depletions? Clark et al. (2019, MNRAS, 489, 5256)
  18. MIR Spectra Starbursts: Engelbracht et al. (2008, ApJ, 678, 804)

    M101 HII regions: Gordon et al. (2008, ApJ, 682, 336) Galaxies: Smith et al. (2007, ApJ, 656, 770)
  19. Stacked Z = 1 LIRGs Stacked Z = 2 ULIRGs

    Fadda et al. (2010, ApJ, 719, 425)
  20. Origin of Dust • Formation: AGB stars, Supernovae, ISM –

    Do we need all 3? • Processing – Growth in ISM – Destruction in supernovae shocks • What are the keys to the dust properties? (testable?)
  21. Formation • Stars: AGB/SN/other sources? – Definitely grains condense from

    the gas phase (SN may destroy all the grains they form?) • ISM – Atoms move from the gas ↔ solid phase • Depletions, ice formation
  22. Magellanic Clouds Excellent census AGB: most dust from a few

    extreme stars (enough)? Transport? Uncertainties? Srinivasan et al. (2016, MNRAS, 457, 2814) Carbon Oxygen Total
  23. Magellanic Clouds SN1987A: ~0.8 M_solar Single source Matsuura et al.

    (2015, ApJ, 800, 50) Indebetouw et al. (2014, ApJL, 78, L2)
  24. Processing • What are the grain properties in AGB/SN? –

    Features? 2175 A, silicates, aromatic/PAH, DIBs, etc. (observationally challenging?) • How important is cycling between diffuse/dense clouds to get observed ISM dust properties? • Is the growth in the ISM → clouds balanced by destruction ← clouds? – Is something left on the grain? (observational signatures?) • Depletions, Gas/Dust Ratio → observational signatures
  25. Magellanic Cloud Depletions Roman-Duval et al. (2019, ApJ, 871, 151)

    Also: Jenkins & Wallerstein (2017, ApJ, 838, 85) LMC: similar to MW? SMC: less depleted See talk by Roman-Duval
  26. Questions • What is dust? • What are the dust

    properties at different z? – Metallicity, redshift, distance in/from a galaxy, ... • What is the origin of dust? – Young stars, evolved stars, ISM, …
  27. Global and Local Geometries with Dust Emission Law, Gordon, &

    Misselt (2018, ApJS, 236, 32) Law, Gordon, & Misselt (2020, in prep)