Revisiting the Local Interstellar Radiation Field using Gaia DR3

TL;DR

This paper presents a revised model of the Local Interstellar Radiation Field (LISRF) based on Gaia DR3 data, showing it is redder and more energetic than previous models, impacting dust emission predictions.

Contribution

A new LISRF model derived from Gaia DR3 and other data, improving accuracy over traditional models and affecting dust emission and grain property interpretations.

Findings

LISRF is ~30% more energetic and redder than previous models.

Diffuse starlight contributes ~25% to total radiation at |b|<50°, three times higher than earlier estimates.

The revised LISRF impacts mid-infrared dust emission predictions.

Abstract

Context: Dust grains in the interstellar medium are heated by the integrated radiation from stars in the Milky Way. A knowledge of the Local Interstellar Radiation Field (LISRF) is thus necessary to interpret observations of dust emission in the infrared and constrain (some of) the properties of interstellar grains. The LISRF representation most widely used in dust modelling still dates back to the seminal works of Mezger et al. (1982) and Mathis et al. (1983). Aims: A new version of the LISRF is presented, starting from the photometry of the Gaia Data Release 3 (DR3) and revisiting available data, among which observations from the Pioneer 10 and 11 probes. Methods: The LISRF contribution by direct starlight is estimated in the Gaia bands by summing fluxes of all stars in DR3; the LISRF is extrapolated from the optical to the ultraviolet and near-infrared, using the astrophysical parameters provided by DR3 for a subsample of Gaia stars; the correlation between dust emission at 100 um and residual diffuse emission in the Pioneer and other available maps is exploited to derive the contribution of dust-scattered starlight to the LISRF. Results: The new LISRF is significantly redder and emits ~30% more energy than the old model. The old LISRF is almost a factor two lower in the near-infrared, while in the optical it accounts only for direct starlight. For |b|<50 degree, diffuse starlight contributes on average to ~25% of the total radiation, 3x more than what predicted by literature estimates at high Galactic latitude. Conclusions: The new LISRF can modify the predicted mid-infrared dust emission beyond the uncertainties normally assumed between dust models and observational constraints; these differences should be taken into account to redefine the properties of small grains and of the carriers of the mid-infrared emission bands.