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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 Exotic Metal Molecules In Oxygen-Rich Envelopes: Detection of AlOH(X 1 Σ + ) In VY Canis Majoris E. D. Tenenbaum and L. M. Ziurys Dept. of Chemistry, Dept. of Astronomy Arizona Radio Observatory Steward Observatory University of Arizona
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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 AlOH: A Short History AlOH: one original molecules studied in Ziurys lab - Rotational spectrum measured by mm direct absorption methods - Measured by Apponi, Barclay, & Ziurys (1993) at ASU Previous electronic spectroscopy by Duncan group Calculations by Shaefer et al. Conducted astronomical searches at NRAO 12 m Sources: Orion, SgrB2, IRC+10216, W Hydra Original spectrometer ASU 1992
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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 ARO Survey of VY CMa and IRC+10216 1 mm survey (210 – 285 GHz) of VY Canis Majoris (VY CMa) and IRC+10216 (Thesis of Emmy Tenenbaum) Conducted with ARO SMT: rms noise level ~ 3 mK IRC+10216: famous carbon-rich circumstellar shell VY CMa is oxygen-rich supergiant - massive circumstellar envelope Explore chemical content O-rich shells Ignored over last few decades Compare with C-rich chemistry Test new Band 6 ALMA mixers SMT VY CMa
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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 283 GHz 284 GHz VY CMa In survey, came across an interesting line…. Frequency of J = 9 → 8 transition of AlOH Found line at J = 7 → 6 frequency Line at J = 5 → 4 frequency (at ARO 12 M) frequencies J = 8 → 7 obscured by SO
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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 Line Parameters for AlOH in VY CMa TransitionFrequency (MHz) ηBηB Θ b (")T R (K)V LSR (km s -1 ) ∆V 1/2 (km s -1 ) J = 9 → 8 283,253.9 0.78273.8 ± 0.721 ± 2.121.2 ± 2.1 J = 8 → 7251,794.80.7831 ---- J = 7 → 6 220,330.9 0.78342.0 ± 0.419 ± 2.716.3 ± 2.7 J = 5 → 4157,391.00.72401.5 ± 0.519 ± 3.823 ± 8 Narrow line profiles for VYCMa V 1/2 typically ~ 40 – 60 km/s AlOH coming from dust acceleration zone gas has not reached terminal velocity 12 13 14 15 16 17 18 19 Log r (cm) R*R* R1R1 Star Dust Shell Acceleration Zone V exp ~ 15 km s -1 T ~ 1000 K 10 10 cm -3 T ~ 25 K 10 5 cm -3 UV
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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 Radiative Transfer Analysis of Lines Code of Bieging and Tafalla (1993) Distance of 1.14 kpc to VY CMa(Choi et al. 2008) Spherical flow: mass loss rate of 2.6 × 10 -4 M yr -1 Collisional rates HCN-H 2 system (none exist for AlOH) V exp ~ 10 km/s: stellar radius ~ 0.13'' (11 R * ) or 2.2 × 10 15 cm Based on H 2 O masers (Richards et al. 1998) r outer ~ 11 R * and r inner ~ 2 R * Best fit to line profiles: f (AlOH/H 2 ) ~ 1 × 10 -7 Source size of ~0.26'' T gas = = -0.62 (Zubko et al 2004) AlOH contains ~ 1% of Al abundance AlOH/AlO ratio ~ 17/1 AlOH dominant carrier of aluminum
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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 LTE Modeling Results AlOH is in dust acceleration zone At r ~ 11 R *, : T ~ 600 K and n(H 2 ) ~ 10 8 cm -3 AlOH formed by LTE chemistry Model calculations (Tsuji 1973): ABUNDANCE vs. STELL RADIUS AlOH abundance f ~10 -6 from 2 to 10 R * (T K ~ 700 – 1500 K) Most abundant Al Species AlO abundance peaks near photosphere at ~ 10 -9 and then drops Abundances of other molecules..
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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 Abundances of Al, Na, and K-bearing Molecules in VY CMa SpeciesObserved Abundance a) LTE-predicted Abundance AlOH1 × 10 -7 2 × 10 -6 NaOH≤ 3 × 10 -9 1 × 10 -7 KOH≤ 1 × 10 -9 8 × 10 -9 AlCl≤ 5 × 10 -8 4 × 10 -8 NaCl4 × 10 -9 1 × 10 -7 KCl≤ 4 × 10 -10 6 × 10 -8 AlO6 × 10 -9 3 × 10 -10 Data from survey Model overestimates AlOH, underestimates AlO Predicts AlCl abundance (upper limit) In general, model overestimates observed abundances
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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 Where are other Metal-Bearing Molecules ? Model predicts KOH, NaOH, KCl in O-rich shells Condensation into grains Shock waves from star Also may be a question of nucleosynthesis Only see Al and Na in molecules in VY CMa Supergiant star likely undergoing H-Shell burning Proton addition to 26 Mg and 22 Ne leads to 27 Al and 23 Na Enrichments of Na and Al observed in M and A-type supergiants (Gonzales and Wallerstein 2000) Clearly need to observe other O-rich envelopes in detail understand chemical trends Other metal hydroxides might be observable in O-rich shells
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65th International Symposium on Molecular Spectroscopy June 21 – 25, 2010 NSF Astronomy NASA Astrobiology
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