Cosmic-ray ionisation rate in low-mass cores: the role of the environment

TL;DR

This study measures cosmic-ray ionisation rates in 20 low-mass starless cores across different environments, revealing a positive correlation with environmental temperature and suggesting local star formation influences cosmic-ray re-acceleration.

Contribution

It provides the first comprehensive comparison of cosmic-ray ionisation rates across diverse low-mass cores and highlights the environmental impact on ionisation levels.

Findings

Ionisation rates vary by nearly two orders of magnitude.

Higher ionisation correlates with warmer environments.

Star-forming regions show elevated cosmic-ray activity.

Abstract

Context: Cosmic rays drive several key processes for the chemistry and dynamical evolution of star-forming regions. Their effect is quantified mainly by means of the cosmic-ray ionisation rate $\zeta_2$. Aims: We aim to obtain a sample of $\zeta_2$ measurements in 20 low-mass starless cores embedded in different parental clouds, to assess the average level of ionisation in this kind of sources and to investigate the role of the environment in this context. The warmest clouds in our sample are Ophiuchus and Corona Australis, where star formation activity is higher than in the Taurus cloud and the other isolated cores we targeted. Methods: We compute $\zeta_2$ using an analytical method based on the {column density} of ortho-$\rm H_2D^+$, the CO abundance, and the deuteration level of HCO$^+$. To estimate these quantities, we analysed new, high-sensitivity molecular line observations obtained with the Atacama Pathfinder EXperiment (APEX) single-dish telescope and archival continuum data from Herschel. Results: We report $\zeta_2$ estimates in 17 cores in our sample and provide upper limits on the three remaining sources. The values span almost two orders of magnitude, from $1.3 \times 10^{-18}\, \rm s^{-1}$ to $8.5 \times 10^{-17}\, \rm s^{-1}$. Conclusions: We find no significant correlation between $\zeta_2$ and the core's column densities $N\rm (H_2)$. On the contrary, we find a positive correlation between $\zeta_2$ and the cores' temperature, estimated via Herschel data: cores embedded in warmer environments present higher ionisation levels. The warmest clouds in our sample are Ophiuchus and Corona Australis, where star formation activity is higher than in the other clouds we targeted. The higher ionisation rates in these regions support the scenario that low-mass protostars in the vicinity of our targeted cores contribute to the re-acceleration of local cosmic rays.