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From bipolar to elliptical : simulating the morphological evolution of planetary nebulae

Please use this identifier to cite or link to this item: http://hdl.handle.net/1959.14/187101

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Title: From bipolar to elliptical : simulating the morphological evolution of planetary nebulae
Related: Monthly notices of the Royal Astronomical Society, Vol. 424, No. 3, (2012), p.2055-2068
DOI: 10.1111/j.1365-2966.2012.21348.x
Publisher: Wiley-Blackwell
Date: 2012
Author/Creator: Huarte-Espinosa, M
Author/Creator: Frank, A
Author/Creator: Balick, B
Author/Creator: Blackman, E.G
Author/Creator: De Marco, O
Author/Creator: Kastner, J. H
Author/Creator: Sahai, R
Description: In this paper we model the evolution of pre-planetary nebula (PPN) and planetary nebula (PN) morphologies as a function of nebular age. The aim of this work is to understand if shape transitions from one evolutionary phase to the other can be driven by changes in the parameters of the mass-loss from the central star. We carry out 2.5D hydrodynamical simulations of mass-loss at the end stages of stellar evolution for intermediate mass stars. Changes in wind velocity, mass-loss rate and mass-loss geometry are tracked. We focus on the transition from mass-loss dominated by a short-duration jet flow (driven during the PPN phase) to mass-loss driven by a spherical fast wind (produced by the central star of the PN). Our results show that while jet-driven nebulae can be expected to be dominated by bipolar morphologies, systems that begin with a jet but are followed by a spherical fast wind will evolve into elliptical objects. Systems that begin with an aspherical asymptotic giant branch wind evolve into butterfly-shaped nebula with, or without, a jet phase. In addition, our models show that spherical nebulae are highly unlikely to derive from either bipolar PPN or elliptical PN over relevant time-scales. The morphological transitions seen in our simulations may however provide insight into the driving mechanisms of both PPN and PN as point to evolutionary changes in the central engine.
Description: 14 page(s)
Subject Keyword: Hydrodynamics
Subject Keyword: Methods: numerical
Subject Keyword: Planetary nebulae: general
Subject Keyword: Radiative transfer
Subject Keyword: Stars: AGB and post-AGB
Subject Keyword: Stars: winds
Subject Keyword: outflows
Resource Type: journal article
Organisation: Macquarie University. Dept. of Physics and Astronomy

Identifier: http://hdl.handle.net/1959.14/187101
Identifier: ISSN:0035-8711
Identifier: mq-rm-2011008933
Identifier: mq_res-ext-2-s2.0-84864515260
Language: eng
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