THEMIS 2.0: A self-consistent model for dust extinction, emission, and polarisation

TL;DR

The paper introduces an updated, flexible dust model called THEMIS 2.0, based on lab-measured optical properties, capable of explaining dust extinction, emission, and polarisation in the diffuse ISM, addressing limitations of previous models.

Contribution

It develops a self-consistent dust model incorporating new optical constants from lab silicates, enabling accurate predictions of polarised dust extinction and emission.

Findings

New optical constants explain observed dust emission and extinction.

Model accounts for variations in polarisation and intensity.

Potential to improve understanding of ISM grain evolution.

Abstract

Recent observations in emission, extinction, and polarisation have at least partially invalidated most of the astronomical standard grain models for the diffuse ISM. Moreover, lab measurements on interstellar silicate analogues have shown differences with the optical properties used in these standard models. To address these issues, our objective is twofold: (i) to update the optical properties of silicates and (ii) to develop the THEMIS dust model to allow the calculation of polarised extinction and emission. Based on optical constants measured in the lab for amorphous silicates and on observational constraints in mid-IR extinction and X-ray scattering, we defined new optical constants for the THEMIS silicates. Absorption and scattering efficiencies for spheroidal grains were then derived with the discrete dipole approximation. These new optical properties make it possible to explain the dust emission and extinction, both total and polarised. The model is not yet pushed to its limits since it does not require the perfect alignment of all grains to explain the observations and it therefore has the potential to accommodate the highest polarisation levels inferred from extinction measures. Moreover, the dispersion of the optical properties of the different lab silicates naturally explain the variations in both the total and polarised emission and extinction observed in the diffuse ISM. A single, invariant model calibrated on one single set of observations is obsolete for explaining contemporary observations. We are proposing a completely flexible dust model based entirely on lab measurements that has the potential to make major advances in understanding the nature of ISM grains and how they evolve as a function of their environment. Even if challenging, this is also relevant for future missions that will aim to perform precise measurements of the CMB spectral distortions and polarisation.