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Post Info TOPIC: Super Planetary Nebulae


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RE: Super Planetary Nebulae
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A team of astronomers have found the missing link in the death of stars, revealing what our sun might look like at the end of its life.
The group of Australian and US astronomers, led by Associate Professor Miroslav Filipovic of the University of Western Sydney, call the new class of object "super planetary nebulae".
They report on their finding in the journal Monthly Notices of the Royal Astronomical Society.


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A team of scientists in Australia and the United States, led by Associate Professor Miroslav Filipovic from the University of Western Sydney, have discovered a new class of object which they call "Super Planetary Nebulae."  They report their work in the journal Monthly Notices of the Royal Astronomical Society.
Planetary nebulae are shells of gas and dust expelled by stars near the end of their lives and are typically seen around stars comparable or smaller in size than the Sun.

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Title: Radio planetary nebulae in the Magellanic Clouds
Authors: M. D. Filipovic, M. Cohen, W. A. Reid, J. L. Payne, Q. A. Parker, E. J. Crawford, I. S. Bojicic, A. Y. De Horta, A. Hughes, J. Dickel and F. Stootman

We report the extragalactic radio-continuum detection of 15 planetary nebulae (PNe) in the Magellanic Clouds (MCs) from recent Australia Telescope Compact Array+Parkes mosaic surveys. These detections were supplemented by new and high-resolution radio, optical and infrared observations which helped to resolve the true nature of the objects. Four of the PNe are located in the Small Magellanic Cloud (SMC) and 11 are located in the Large Magellanic Cloud (LMC). Based on Galactic PNe the expected radio flux densities at the distance of the LMC/SMC are up to ~2.5 and ~2.0 mJy at 1.4 GHz, respectively. We find that one of our new radio PNe in the SMC has a flux density of 5.1 mJy at 1.4 GHz, several times higher than expected. We suggest that the most luminous radio PN in the SMC (N S68) may represent the upper limit to radio-peak luminosity because it is approximately three times more luminous than NGC 7027, the most luminous known Galactic PN. We note that the optical diameters of these 15 Magellanic Clouds (MCs) PNe vary from very small (~0.08 pc or 0.32 arcsec; SMP L47) to very large (~1 pc or 4 arcsec; SMP L83). Their flux densities peak at different frequencies, suggesting that they may be in different stages of evolution. We briefly discuss mechanisms that may explain their unusually high radio-continuum flux densities. We argue that these detections may help solve the 'missing mass problem' in PNe whose central stars were originally  1- 8 Solar masses . We explore the possible link between ionised haloes ejected by the central stars in their late evolution and extended radio emission. Because of their higher than expected flux densities, we tentatively call this PNe (sub)sample -'Super PNe'.

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