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http://dx.doi.org/10.5303/PKAS.2015.30.2.163

KINEMATICAL PROPERTIES OF PLANETARY NEBULAE WITH WR-TYPE NUCLEI  

DANEHKAR, ASHKBIZ (Department of Physics and Astronomy, Macquarie University)
STEFFEN, WOLFGANG (Instituto de Astronomia, Universidad Nacional Autonoma de Mexico)
PARKER, QUENTIN A. (Department of Physics and Astronomy, Macquarie University)
Publication Information
Publications of The Korean Astronomical Society / v.30, no.2, 2015 , pp. 163-167 More about this Journal
Abstract
We have carried out integral field unit (IFU) spectroscopy of $H{\alpha}$, [$N{\small{II}}$] and [$O{\small{III}}$] emission lines for a sample of Galactic planetary nebulae (PNe) with Wolf-Rayet (WR) stars and weak emission-line stars (wels). Comparing their spatially-resolved kinematic observations with morpho-kinematic models allowed us to disentangle their three-dimensional gaseous structures. Our results indicate that these PNe have axisymmetric morphologies, either bipolar or elliptical. In many cases the associated kinematic maps for the PNe around hot central stars also reveal the presence of so-called fast low-ionization emission regions.
Keywords
planetary nebulae: general; ISM: kinematics and dynamics; stars: Wolf-Rayet;
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1 Akras S., & Lopez J. A., 2012, Three-dimensional Modelling of the Collimated Bipolar Outflows of Compact Planetary Nebulae with Wolf-Rayet-type Central Stars, MNRAS, 425, 2197   DOI   ScienceOn
2 Balick B., 1987, The Evolution of Planetary Nebulae. I - Structures, Ionizations, and Morphological Sequences, AJ, 94, 671   DOI
3 Balick B., Perinotto M., Maccioni A., Terzian Y., & Hajian A., 1994, FLIERs and other microstructures in planetary nebulae, 2, ApJ, 424, 800   DOI
4 Balick B., & Frank A., 2002, Shapes and Shaping of Planetary Nebulae, ARA&A, 40, 439   DOI   ScienceOn
5 Danehkar A., Parker Q. A., & Ercolano B., 2013, Observations and Three-dimensional Ionization Structure of the Planetary Nebula SuWt 2, MNRAS, 434, 1513   DOI
6 Danehkar A., 2014, Evolution of Planetary Nebulae with WR-type Central Stars, PhD thesis, Macquarie University
7 Danehkar A., Todt H., Ercolano B., & Kniazev A. Y., 2014, Observations and Three-dimensional Photoionization Modelling of the Wolf-Rayet Planetary Nebula Abell 48, MNRAS, 439, 3605   DOI
8 Dopita M., et al., 2010, The Wide Field Spectrograph (WiFeS): Performance and Data Reduction, Ap&SS, 327, 245   DOI
9 Frank A. & Blackman E. G., 2004, Application of Magnetohydrodynamic Disk Wind Solutions to Planetary and Protoplanetary Nebulae, ApJ, 614, 737   DOI
10 Garcia-Segura G., & Lopez J. A., 2000, Three-dimensional Magnetohydrodynamic Modeling of Planetary Nebulae. II. The Formation of Bipolar and Elliptical Nebulae with Point-symmetric Structures and Collimated Out-flows, ApJ, 544, 336   DOI
11 Garcia-Segura, G., Villaver, E., Langer, N., Yoon, S.-C., & Manchado, A., 2014, Single Rotating Stars and the Formation of Bipolar Planetary Nebula, ApJ, 783, 74   DOI
12 Goncalves D. R., Mampaso A., Corradi R. L. M., & Quireza C., 2009, Low-ionization Pairs of Knots in Planetary Nebulae: Physical Properties and Excitation, MNRAS, 398, 2166   DOI   ScienceOn
13 Gorny S. K., Schwarz H. E., Corradi R. L. M., & Van Winckel H., 1999, An Atlas of Images of Planetary Nebulae, A&AS, 136, 145   DOI   ScienceOn
14 Kahn F. D. & West K. A., 1985, Shapes of Planetary Nebulae, MNRAS, 212, 837   DOI
15 Kastner J. H., Montez, Jr. R., Balick B., & De Marco O., 2008, Serendipitous Chandra X-Ray Detection of a Hot Bubble within the Planetary Nebula NGC 5315, ApJ, 672, 957   DOI
16 Kastner J. H., et al., 2012, The Chandra X-Ray Survey of Planetary Nebulae (CHANPLANS): Probing Binarity, Magnetic Fields, and Wind Collisions, AJ, 144, 58   DOI   ScienceOn
17 Markwardt C. B., 2009, in ASP Conf. Ser. Vol. 411, p. 251
18 Kwok S., Purton C. R., & Fitzgerald P. M., 1978, On the origin of Planetary Nebulae, ApJ, 219, L125   DOI
19 Kwok S., 2010, Morphological Structures of Planetary Nebulae, Publ. Astron. Soc. Australia, 27, 174   DOI
20 Lopez J. A., Steffen W., & Meaburn J., 1997, Bipolar, Collimated Outbursts in the Planetary Nebula Hb 4, ApJ, 485, 697   DOI
21 Montez, Jr. R., Kastner J. H., De Marco O., & Soker N., 2005, X-Ray Imaging of Planetary Nebulae with Wolf-Rayet-type Central Stars: Detection of the Hot Bubble in NGC 40, ApJ, 635, 381   DOI
22 Nordhaus J. & Blackman E. G., 2006, Low-mass Binary-induced Outflows from Asymptotic Giant Branch Stars, MNRAS, 370, 2004   DOI   ScienceOn
23 Parker Q. A., Phillipps S., & Pierce M., et al., 2005, The AAO/UKST Super COSMOS H Survey, MNRAS, 362, 689   DOI   ScienceOn
24 Sahai R., Morris M. R., & Villar G. G., 2011, Young Planetary Nebulae: Hubble Space Telescope Imaging and a New Morphological Classi cation System, AJ, 141, 134   DOI   ScienceOn
25 Schwarz H. E., Corradi R. L. M., & Melnick J., 1992, A Catalogue of Narrow Band Images of Planetary Nebulae, A&AS, 96, 23
26 Stanghellini L., Corradi R. L. M., & Schwarz H. E., 1993, The Correlations Between Planetary Nebula Morphology and Central Star Evolution, A&A, 279, 521
27 Steffen W. & Lopez J. A., 2006, Morpho-Kinematic Modeling of Gaseous Nebulae with SHAPE, RMxAA, 42, 99
28 Steffen W., Koning N., Wenger S., Morisset C., & Magnor M., 2011, IEEE Trans. Vis. Comput. Graphics, 17, 454   DOI   ScienceOn
29 Soker N., 2006, Why Magnetic Fields Cannot Be the Main Agent Shaping Planetary Nebulae, PASP, 118, 260   DOI   ScienceOn
30 Steffen, W., Koning, N., & Esquivel, A., et al., 2013, A Wind-shell Interaction Model for Multipolar Planetary Nebulae, MNRAS, 436, 470   DOI