Gaia DR2 giants in the Galactic dust -- II. Application of the reddening maps and models

TL;DR

This paper uses Gaia DR2 data to analyze the spatial variations of reddening in the Galaxy by applying an advanced 3D dust model, GM20, which incorporates complex dust layer structures and compares favorably with other models.

Contribution

It introduces GM20, an improved 3D dust distribution model with detailed dust layers and variations, and demonstrates its effectiveness in explaining Gaia DR2 giant star reddening.

Findings

GM20 provides accurate reddening estimates consistent with Gaia data.

GM20 outperforms several existing 3D reddening models in predicting observed color modes.

The dust layer in GM20 has specific scale heights and spatial features aligned with Galactic structures.

Abstract

We exploit a complete sample of 101\,810 {\it Gaia} DR2 giants, selected in Paper I in the space cylinder with a radius of 700 pc around the Sun and a height of $|Z|=1800$ pc, using the {\it Gaia} DR2 parallaxes, $G_\mathrm{BP}$ and $G_\mathrm{RP}$ photometry, and {\it WISE} $W3$ photometry. We explain the spatial variations of the modes of the observables $G_\mathrm{BP}-G_\mathrm{RP}$ and $G_\mathrm{RP}-W3$ by the spatial variations of the corresponding reddenings described in the GM20 3D dust distribution model. Presented in this paper, GM20 is an advanced version of the model introduced by Gontcharov in 2009. GM20 proposes two intersecting dust layers, along the Galactic mid-plane and in the Gould Belt, with exponential vertical and sinusoidal longitudinal variations of the dust spatial density in each layer. The Belt layer is an ellipse, oriented nearly between the centre and anticentre of the Galaxy, and with a semi-major and semi-minor axes of 600 and 146~pc, respectively. $G_\mathrm{BP}-G_\mathrm{RP}$ and $G_\mathrm{RP}-W3$ give similar solutions, but different equatorial layer scale heights of $150\pm15$ and $180\pm15$~pc, respectively, and $(G_\mathrm{BP}-G_\mathrm{RP})_0=(1.14\pm0.01)-(0.022\pm0.010)\,|Z|$, $(G_\mathrm{RP}-W3)_0=(1.44\pm0.01)-(0.015\pm0.010)\,|Z|$, where $Z$ is in kpc. We compare GM20 with several 3D reddening models and maps in their ability to predict the observed colour modes. GM20 and the 3D map by Gontcharov appear to be the best among the models and maps, respectively. However, the most reliable models and maps mainly disagree only in their estimates of low reddening, including the reddening across the whole dust layer.