Smash and grab: A heavyweight stellar champion for dying stars

PNe理论上推导的星星距离1-8 times the mass of the Sun, representing 90% of all stars more massive than the sun. However, until now, PNe have been proven to derive from stars born with only 1-3 times the mass of our Sun. Professor Quentin Parker, Department of Physics and Director of The Laboratory for Space Research, The University of Hong Kong and his PhD student Miss Fragkou Vasiliki, in collaboration with University of Manchester and South African Astronomical Observatory, have now officially smashed this previous limit and grabbed the proof that a PNe has emerged from a star born with 5.5 times the mass of our Sun. Their journal paper "A high-mass planetary nebula in a Galactic open cluster" has just been published on theNature Astronomy's website.

But why is this important?

Firstly, PNe provide a unique window into the soul of late stage stellar evolution revealed by their rich emission line spectra that are excellent laboratories for plasma physics. PNe are visible to great distances where their strong lines permit determination of the size, expansion velocity and age of the PN, so probing the physics and timescales of stellar mass loss. They can also be used to derive luminosity, temperature and mass of their central remnant stellar cores, and the chemical composition of the ejected gas.

其次,关键是,这是一个unprecedented example of a star whose proven original "progenitor" mass is close to the theoretical lower limit of core-collapse supernova formation. Our results are the first solid evidence confirming theoretical predictions that 5+ solar mass stars can actually form PNe. This unique case therefore provides the astronomical community with an important tool for fresh insights into stellar and Galactic chemical evolution.

But how did the team from The University of Hong Kong and the University of Manchester claim the heavyweight crown?

The key was the discovery of the PNe in a young, Galactic open cluster called NGC6067. Finding a PNe residing in an open cluster is an extremely rare event. Indeed, only one other PNe, "PHR1615-6555" has ever been previously proven to reside on an open cluster but whose progenitor star had considerably lower mass. Interestingly, this was an earlier discovery from the same led team as here. The proven location of a PN in a cluster provides key and important data that is difficult to acquire otherwise. This includes an accurate distance and a cluster "turn off" mass estimate (i.e. the mass a star must have had when it was born to now be seen evolving off the main sequence in the cluster of known age). High confidence in the PN-cluster association comes from their highly consistent radial velocities (to better tan 1km/s) in a sight-line with a steep velocity-distance gradient, common distances, common reddening and projected and close physical proximity of the PN to the cluster centre.

In summary our exciting results are solid evidence confirming theoretical predictions that 5+ solar mass stars can form planetary nebulae and are, as expected, Nitrogen rich. The PN's cluster membership provides fresh and tight constraints on the lower mass limit for the progenitor mass of core-collapse supernovae and also for the intermediate to high mass end of the white dwarf Initial to Final Mass Relation (IFMR). It also provides an empirical benchmark for evaluating nucleosynthetic (element creation) predictions for intermediate-mass stars. PN BMPJ1613-5406 and its cluster NGC6067 will provide the astronomical community with important insights into stellar and Galactic (chemical) evolution.