Mathematics – Logic
Scientific paper
Dec 2002
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2002aas...201.2208s&link_type=abstract
American Astronomical Society, 201st AAS Meeting, #22.08; Bulletin of the American Astronomical Society, Vol. 34, p.1142
Mathematics
Logic
Scientific paper
The imaging of young planetary and pre-planetary nebulae (PNe and PPNe) with unprecedented high angular resolution and dynamic range using the Hubble Space Telescope (HST), has led to the realisation that almost all of these objects are highly aspherical, with complex multipolar morphologies. The complexity, organization and symmetry of the morphological structures demands radical changes in our understanding of the mass-loss processes during late stellar evolution. We have therefore proposed a model for PN formation in which the primary agent for shaping PNe are high-speed collimated outflows or jets which operate during the late AGB and/or early post-AGB evolutionary phase. Episodic changes in their orientation (or the operation of multiple outflows which operate quasi-simultaneously with different orientations) may explain the widespread presence of multipolar structures and/or point-symmetric morphologies in these objects. In this paper, we briefly describe the results from imaging surveys of young PNe and PPNe with HST, and then present new results from detailed kinematic studies of several prominent objects which support our hypothesis for shaping PNe. For example, STIS observations of V Hydrae, a carbon-rich AGB star, show extended forbidden-line emission from a very young (about 2 yrs) high-speed (190-260 km s-1) outflow which most likely consists of more than one kinematic component with differing orientations. In the PPN He3-1475, STIS data shows a very young (kinematic age few x 10 yr), high-velocity (2300 km s-1) outflow, collimated close to the central star, along an axis that is misaligned with the bipolar nebula at the center. In CRL618, a PPN currently evolving into a PN (and showing several highly-collimated lobes clustered along the optical axis of the nebula in HST images), we have used ground-based long-slit spectroscopy to study the physical structure of the lobes. We describe a new effort to infer the properties of the fast outflows by modelling specific objects (e.g. CRL618) using numerical simulations of the hydrodynamic interaction of fast collimated outflows with slow spherical circumstellar winds.
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