Frosty Leo Nebula
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| Frosty Leo Nebula | |
 2003 Hubble Advanced Camera for Surveys HRC |
|
| Observation data (Epoch J2000) | |
|---|---|
| Right ascension | 09h 39m 53.96s[1] |
| Declination | +11° 58′ 52.4″[1] |
| Distance | 3.0 kly (920 pc)[2] |
| Apparent magnitude (V) | 11[3] |
| Apparent dimensions (V) | 25″[4] |
| Constellation | Leo |
| Physical characteristics | |
| Radius | 0.18 ly[a] |
| Absolute magnitude (V) | 1.2[b] |
| Notable features | Crystalline Ice, Point Reflection Symmetry |
| Other designations | IRAS 09371+1212[1] |
| See also: Protoplanetary nebula, Lists of nebulae | |
The Frosty Leo Nebula is a protoplanetary nebula (PPN) located roughly at 3,000 light-years (Davis et al. 2005) away from Earth in the direction of the constellation Leo. It is a spectral[4] bipolar nebula. Its central star is of optical spectral type K7II.[2] It is unusual in that it has an extremely deep absorption feature at 3.1µm and is unusually located at more than 900 pc above the plane of our galaxy.(Bourke et al. 2000) Further, as of 1990, it has the only known PPN circumstellar outflow in which crystalline ice dominates the long-wavelength emission spectrum and the only known PPN with point-reflection-symmetric deviations from axial symmetry.[5]
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[edit] Characteristics
The Frosty Leo Nebula has two lobes that are separated by 2″ between which is an almost edge-on dust ring.[5] It also has two relatively faint but prominent compact nebulosities, or ansae, separated by ~23″ along the polar axis of the PPN.[5] The PPN as a whole has an hourglass like shape. It has an inclination angle of 15° relative to the plane of the sky.[2] Its molecular envelope is expanding at a rate of ~25 km/s.[6]
[edit] Observation history
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This PPN was first noticed in the IRAS survey due to its exceptionally cold IRAS color temperatures.[5] It also has a uniquely sharp maximum at 60-μM.[6]
[edit] Point symmetry
It is the first bipolar PPN known to have point reflection symmetry (all others being axially symmetric).[5] Point symmetry is a fairly common trait of planetary nebulae as found in NGC 2022, NGC 2371-2, NGC 6309, Cat's Eye Nebula, NGC 6563, Dumbbell Nebula, Saturn Nebula, A24, and Hb5.[5] Morris & Reipurth 1990 postulate that point symmetry is either due to the bipolar outflow being directed by a precessing disc or a precessing common envelope binary.
[edit] Naming
Forveille et al. 1987 dubbed IRAS 09371+1212 as the "Frosty Leo Nebula" because of their interpretation of the object's extremely unusual far infrared spectrum that water is largely depleted in its gaseous state by ice condensation into grains and for its location in the Leo constellation. Their interpretation was subsequently verified in 1988 by three independent papers.[5] Omont et al. 1990 further observed in the band between 35 to 65 μM that very cold (<50 K) silicate dust grains, abundantly coated with crystalline ice, are responsible for the 60-μM excess.[5]
[edit] Notes
- ^ 3.0 kly × sin( 25″ / 2 ) = 0.18 ly. radius
- ^ 11[3] apparent magnitude - 5 * (log10(920 pc distance) - 1) = 1.2 absolute magnitude
- ^ a b c (SIMBAD 2007)
- ^ a b c (Davis et al. 2005)
- ^ a b (Beuzit et al. 1994)
- ^ a b (Omont et al. 1990)
- ^ a b c d e f g h (Morris & Reipurth 1990)
- ^ a b (Forveille et al. 1987)
[edit] References
- Beuzit, J.-L.; P. Thebault & G. Perrin et al. (November 1994), "Adaptive optics imaging of the Frosty Leo nebula", Astronomy and Astrophysics (ISSN 0004-6361) 291 (1): L1-L4, <http://adsabs.harvard.edu/abs/1994A&A...291L...1B>
- Bourke, Tyler; A. R. Hyland & Garry Robinson et al. (2000), "The Evolutionary Status of the Frosty Leo Nebula", Asymmetrical Planetary Nebulae II: From Origins to Microstructures, ASP Conference Series. Edited by J. H. Kastner, N. Soker, and S. Rappaport. ISBN 1-58381-026-9 199 (1): 171, <http://adsabs.harvard.edu/cgi-bin/nph-bib_query?bibcode=2000ASPC..199..171B>
- Davis, C. J.; M. D. Smith & T. M. Gledhill et al. (2005), "Near-infrared echelle spectroscopy of protoplanetary nebulae: probing the fast wind in H2", Monthly Notices of the Royal Astronomical Society 360 (1): 104-118, <http://adsabs.harvard.edu/cgi-bin/nph-bib_query?bibcode=2005MNRAS.360..104D>
- Forveille, T.; M. Morris & A. Omont et al. (April 1987), "IRAS 09371+1212 - an icy evolved, mass-losing star with a unique IR spectrum", Astronomy and Astrophysics (ISSN 0004-6361) 176 (1): L13-L16, <http://adsabs.harvard.edu/abs/1987A%26A...176L..13F>
- Morris, Mark & Bo Reipurth (April 1990), "The optical form of the bipolar preplanetary nebula IRAS 09371 + 1212", Astronomical Society of the Pacific, Publications (ISSN 0004-6280) 102: 446-453, <http://adsabs.harvard.edu/abs/1990PASP..102..446M>
- Omont, A.; T. Forveille & S. H. Moseley et al. (May 20, 1990), "Observations of 40-70 micron bands of ice in IRAS 09371 + 1212 and other stars", Astrophysical Journal, Part 2 - Letters (ISSN 0004-637X) 355: L27-L30, <http://adsabs.harvard.edu/abs/1990ApJ...355L..27O>
- SIMBAD (January 7, 2007), Results for Frosty Leo Nebula, SIMBAD, Centre de Données Astronomiques de Strasbourg, <http://simbad.u-strasbg.fr/simbad/sim-id?protocol=html&Ident=Frosty+Leo+Nebula>
