From pre- to young Planetary Nebulae: radio continuum variability

TL;DR

This study investigates radio continuum variability in young planetary nebulae, revealing diverse behaviors such as flux increase, decrease, and periodicity, which inform understanding of ionisation progression and stellar wind activity.

Contribution

It provides the first detailed radio variability analysis of young planetary nebulae, highlighting different temporal behaviors and their implications for nebular evolution.

Findings

IRAS 18062+2410's ionised mass increased over 8 years.

IRAS 17423-1755 shows possible periodic radio flux variation.

Some sources exhibit decreasing radio flux, indicating complex stellar wind dynamics.

Abstract

Searching for variability, we have observed a sample of hot post-AGB stars and young Planetary Nebulae candidates with the Very Large Array at 4.8, 8.4, and 22.4 GHz. The sources had been previously detected in the radio continuum, which is a proof that the central stars have started ionising their circumstellar envelopes and an increase in radio flux with time can be expected as a result of the progression of the ionisation front. Such a behaviour has been found in IRAS 18062+2410, whose radio modelling has allowed us to determine that its ionised mass has increased from 10^{-4} to 3.3 10^{-4} M_sun in 8 years and its envelope has become optically thin at lower frequencies. Different temporal behaviours have been found for three other sources. IRAS 17423-1755 has shown a possibly periodic pattern and an inversion of its radio spectral index, as expected from a varying stellar wind. We estimate that the radio flux arises from a very compact region around the central star (10^{15} cm) with an electron density of 2 10^6 cm^{-3}. IRAS 22568+6141 and 17516-2525 have decreased their radio flux densities of about 10% per year over 4 years. While a linear increase of the flux density with time points out to the progression of the ionisation front in the envelope, decreases as well as quasi-periodic patterns may indicate the presence of unstable stellar winds/jets or thick dusty envelopes absorbing ionising photons.