Modelling the spinning dust emission from dense interstellar clouds

TL;DR

This study models spinning dust emission in dense interstellar clouds considering realistic physical conditions and radiative transfer, revealing its sensitivity to local ion abundances and cosmic-ray rates, and its potential to trace grain growth.

Contribution

It introduces a detailed modeling approach incorporating radiative transfer and local physical conditions to better understand spinning dust emission in dense clouds.

Findings

Spinning dust emission is sensitive to ion abundances.

Emission can be strong at cloud centers despite weak PAH mid-IR emission.

Relationship between spinning dust and PAH mid-IR emission is non-linear in dense media.

Abstract

Electric dipole emission arising from PAHs is often invoked to explain the anomalous microwave emission (AME). This assignation is based on an observed tight correlation between the mid-IR emission of PAHs and the AME; and a good agreement between models of spinning dust and the broadband AME spectrum. So far often detected at large scale in the diffuse interstellar medium, the AME has recently been studied in detail in well-known dense molecular clouds with the help of Planck data. While much attention has been given to the physics of spinning dust emission, the impact of varying local physical conditions has not yet been considered in detail. Our aim is to study the emerging spinning dust emission from interstellar clouds with realistic physical conditions and radiative transfer. We use the DustEM code from Compiegne et al. to describe the extinction and IR emission of all dust populations. The spinning dust emission is obtained with SpDust, as described by Silsbee et al., that we have coupled to DustEM. We carry out full radiative transfer simulations and carefully estimate the local gas state as a function of position within interstellar clouds. We show that the spinning dust emission is sensitive to the abundances of the major ions and we propose a simple scheme to estimate these abundances. We also investigate the effect of changing the cosmic-ray rate. In dense media, where radiative transfer is mandatory, we show that the relationship between the spinning and mid-IR emissivities of PAHs is no longer linear and that the spinning dust emission may actually be strong at the centre of clouds where the mid-IR PAH emission is weak. These results provide new ways to trace grain growth from diffuse to dense medium and will be useful for the analysis of AME at the scale of interstellar clouds.