The H\alpha\ surface brightness - radius relation: a robust statistical distance indicator for planetary nebulae

TL;DR

The paper introduces a new, robust optical statistical distance indicator for Galactic planetary nebulae based on the Hα surface brightness-radius relation, significantly improving distance measurements accuracy.

Contribution

It develops and calibrates the S-r relation using high-quality data, enabling precise distance estimates and expanding the largest catalog of PNe distances to date.

Findings

Achieved distance accuracy as good as 18% for certain PNe types.

Created the largest catalog of PNe distances with over 1100 entries.

Demonstrated the S-r relation's diagnostic capability for different nebulae types.

Abstract

Measuring the distances to Galactic planetary nebulae (PNe) has been an intractable problem for many decades. We have now established a robust optical statistical distance indicator, the H$\alpha$ surface brightness- radius or S-r relation, which addresses this problem. We developed this relation from a critically evaluated sample of primary calibrating PNe. The robust nature of the method results from our revised calibrating distances with significantly reduced systematic uncertainties, and the recent availability of high-quality data, including updated nebular diameters and integrated H$\alpha$ fluxes. The S-r technique is simple in its application, requiring only an angular size, an integrated H\alpha\ flux, and the reddening to the PN. From these quantities, an intrinsic radius is calculated, which when combined with the angular size, yields the distance directly. Furthermore, we have found that optically thick PNe tend to populate the upper bound of the trend, while optically-thin PNe fall along the lower boundary in the S-r plane. This enables sub-trends to be developed which offer even better precision in the determination of distances, as good as 18 per cent in the case of optically-thin, high-excitation PNe. This is significantly better than any previous statistical indicator. We use this technique to create a catalogue of statistical distances for over 1100 Galactic PNe, the largest such compilation in the literature to date. Finally, in an appendix, we investigate both a set of transitional PNe and a range of PN mimics in the S-r plane, to demonstrate its use as a diagnostic tool. Interestingly, stellar ejecta around massive stars plot on a tight locus in S-r space with the potential to act as a separate distance indicator for these objects.