CLASSY VI: Density, Structure and Size of Galactic Outflows

TL;DR

This study introduces a method to measure electron density in galactic outflows using absorption lines, providing new insights into outflow structure, cloud properties, and their relation to star formation in local galaxies.

Contribution

It presents a novel technique to directly determine gas electron density and outflow distances from absorption line data, enhancing understanding of galactic wind structures.

Findings

Electron density correlates with star formation rate per unit area.

Outflow cloud sizes are large enough to survive wind interactions.

First-ever absorption line measurements of galactic wind properties.

Abstract

Galaxy formation and evolution are regulated by the feedback from galactic winds. Absorption lines provide the most widely available probe of winds. However, since most data only provide information integrated along the line-of-sight, they do not directly constrain the radial structure of the outflows. In this paper, we present a method to directly measure the gas electron density in outflows (ne), which in turn yields estimates of outflow cloud properties (e.g., density, volume filling-factor, and sizes/masses). We also estimate the distance (r) from the starburst at which the observed densities are found. We focus on 22 local star-forming galaxies primarily from the COS Legacy Archive Spectroscopic SurveY (CLASSY). In half of them, we detect absorption lines from fine structure excited transitions of Si II (i.e., Si II*). We determine ne from relative column densities of Si II and Si II*, given Si II* originates from collisional excitation by free electrons. We find that the derived ne correlates well with the galaxy's star-formation rate per unit area. From photoionization models or assuming the outflow is in pressure equilibrium with the wind fluid, we get r ~ 1 to 2 * rstar or ~ 5 * rstar, respectively, where rstar is the starburst radius. Based on comparisons to theoretical models of multi-phase outflows, nearly all of the outflows have cloud sizes large enough for the clouds to survive their interaction with the hot wind fluid. Most of these measurements are the first-ever for galactic winds detected in absorption lines and, thus, will provide important constraints for future models of galactic winds.