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Ralf Siebenmorgen Toulouse June’10 Dust model of the ISM PAH bands in starburst nuclei Monte Carlo radiative transfer PAH destruction in T Tauri disks Frank Heymann (PhD) Endrik Krűgel
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Ralf Siebenmorgen Toulouse June’10 dust’1990
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Ralf Siebenmorgen Toulouse June’10 spheroids 1: polarisation Voshchinnikov (2004)
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Ralf Siebenmorgen Toulouse June’10 2: ‘’2200” bump + 3: PAH absorption Vertraete et al. 1992 Malloci et al. 2007 Schutte et al. 1993 PAH gr
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Ralf Siebenmorgen Toulouse June’10 Si + aC : 60Å < a < 0.2-0.3µm, ~a -3.5 Graphite: 5Å < a < 80 Å, ~a -3.5 PAH : 30, 200 C ISM [g]: 0.66Si + 0.22aC + 0.07gr + 0.05 PAH [g] extinction’2010
![Ralf Siebenmorgen Toulouse June’10 Si + aC : 60Å < a < µm, ~a -3.5 Graphite: 5Å < a < 80 Å, ~a -3.5 PAH : 30, 200 C ISM [g]: 0.66Si aC gr PAH [g] extinction’2010](http://images.slideplayer.com/34/8372322/slides/slide_5.jpg "Ralf Siebenmorgen Toulouse June’10 Si + aC : 60Å < a < µm, ~a -3.5 Graphite: 5Å < a < 80 Å, ~a -3.5 PAH : 30, 200 C ISM [g]: 0.66Si aC gr PAH [g] extinction’2010")
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Ralf Siebenmorgen Toulouse June’10 mean I S R F
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Ralf Siebenmorgen Toulouse June’10 “Carbon crisis” abundances [ppm]: 31Si + 150aC + 50gr + 30PAH 4: abundance + 5: PAH bands
![Ralf Siebenmorgen Toulouse June’10 Carbon crisis abundances [ppm]: 31Si + 150aC + 50gr + 30PAH 4: abundance + 5: PAH bands](http://images.slideplayer.com/34/8372322/slides/slide_7.jpg "Ralf Siebenmorgen Toulouse June’10 Carbon crisis abundances [ppm]: 31Si + 150aC + 50gr + 30PAH 4: abundance + 5: PAH bands")
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Ralf Siebenmorgen Toulouse June’10 dust’2010
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Ralf Siebenmorgen Toulouse June’10 ISO Boulanger et al. (1998) Siebenmorgen et al. (1998) HD97300
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Ralf Siebenmorgen Toulouse June’10 Siebenmorgen et al. (2001) NGC1808 Radiative transfer in SB
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Ralf Siebenmorgen Toulouse June’10 post ISO 17 features
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Ralf Siebenmorgen Toulouse June’10 Siebenmorgen et al. (2001) post ISO
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Ralf Siebenmorgen Toulouse June’10 Siebenmorgen et al. (2007) post Spitzer SED model grid: luminosity size mass
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Ralf Siebenmorgen Toulouse June’10 high z Efstathiou & Siebenmorgen (2009)
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Ralf Siebenmorgen Toulouse June’10 Original code by Krűgel (2006) Arbitrary dust distribution Pseudo adaptive mesh 1. geometry Monte Carlo
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Ralf Siebenmorgen Toulouse June’10 1. geometry 2. source Source emits “photon packages” of equal energy Monte Carlo
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Ralf Siebenmorgen Toulouse June’10 1. geometry 2. source 3. inter-action 4. dust temperature absorption / scattering / no interaction Monte Carlo = - ln( ζ)
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Ralf Siebenmorgen Toulouse June’10 Photons escape model cloud Monte Carlo 1. geometry 2. source 3. inter-action 4. temperature 5. detection
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Ralf Siebenmorgen Toulouse June’10 store PAH absorption events of each cell compute PAH emission neglect PAH self absorption Monte Carlo + PAH
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Ralf Siebenmorgen Toulouse June’10 Multiple photons at a time: MC parallelization 1.Cell locked when hit by photon 2.Parallel random number generator (Mersene Twister) 3.Computer games Graphical Processing Units (CUDA)
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Ralf Siebenmorgen Toulouse June’10 1D benchmark sphere Iveciz (99)
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Ralf Siebenmorgen Toulouse June’10 1D benchmark sphere T * = 2500K ρ (r) = const. A V =10 1 1001000 mag ~5% for 0
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Ralf Siebenmorgen Toulouse June’10 Method ParallelizationAdvantage Time Benchmark sphere τ~1000) Lucy YES (but floating) Optical thin>1h Bjorkman & Wood Partly (not independent) No iteration5min ourYESGPU<1min MC methods
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Ralf Siebenmorgen Toulouse June’10 Monte Carlo + PAH
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Ralf Siebenmorgen Toulouse June’10 Disk: T * = 5800K L * = L sun ρ (r) : hydro static equilibrium (Chiang & Goldreich 1997) Pascucci et al (2004) 2D benchmark
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Ralf Siebenmorgen Toulouse June’10 2D benchmark disk 0 ~10% for face-on edge-on 1 = 10 100
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Ralf Siebenmorgen Toulouse June’10 3D proto-planetary disk + spiral MHD (Fargo) density T * = 5800K L * = L sun A v =10mag 8au 3au
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Ralf Siebenmorgen Toulouse June’10 3D proto-planetary disk + spiral
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Ralf Siebenmorgen Toulouse June’10 ELT 42m PAH imaging
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Ralf Siebenmorgen Toulouse June’10 D = 50pc 50mas at 11.3μm PSF dual band + coronograph ELT 42m PAH imaging
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Ralf Siebenmorgen Toulouse June’10 D = 50pc 50mas at 11.3μm PAH imaging gap /px (μJy /px)
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Ralf Siebenmorgen Toulouse June’10 PAH detection rate: Herbig AeBe 60% TTS 10% T Tauri stars
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Ralf Siebenmorgen Toulouse June’10 T Tauri stars
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Ralf Siebenmorgen Toulouse June’10
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PAH in a mono-energetic heating bath if | U f – U i – hν | < ½ ΔU f : A fi = K ν F ν / hν Siebenmorgen & Krűgel (2010)
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Ralf Siebenmorgen Toulouse June’10 Arrhenius form: t dis ~ exp(E o /kT) / ν 0 « t cool /f ~ 1s T min = E o /k ln(ν 0 ) ~2000K; E b ~ 5eV; ν 0 = 10 13 Hz ΔE = 3N c kT min ~ 0.1 N c. E o => N c < 2 ΔE /[eV] (PAH unstable) EoEo T [K] time t cool t abs ~ 1h Omont (1986); Micedlotta et al. (2010); Tielens (2005) Unimolecular dissociation: PAH destruction
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Ralf Siebenmorgen Toulouse June’10 Unimolecular dissociation: t dis ~ exp(E o /kT) / ν 0 « t cool /f ~ 1s T min = E o /k ln(ν 0 ) ~2000K; E o ~ 5eV ΔE = 3N c kT min ~ 0.1 N c. E o => N c < 2 ΔE /[eV] (PAH unstable) EoEo PAH destruction 1) single hard photon : independent of distance 2) many soft photons : ~ 1AU
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Ralf Siebenmorgen Toulouse June’10 Stationary disk Sufficient X-ray photons? α ℓ τ = 1 z I } # C in PAH # hard γ absorption/sec << TT phase ‘PAH removal time’ top surface layer Σ ℓ = α/κ = h ν ∙ 4 π r 2 /Lκ
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Ralf Siebenmorgen Toulouse June’10 Vertical mixing in disk? ℓ /v ┴ = t exp > N C t abs PAH replenishment Siebenmorgen & Krűgel (2010)
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Ralf Siebenmorgen Toulouse June’10 Future Heating: photosph.+FEUV + X-rays Dust + Gas Density structure PAH emission + destruction MC model of T Tauri disks
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Ralf Siebenmorgen Toulouse June’10 Conclusion ?
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