A High Precision Survey of the D/H Ratio in the Nearby Interstellar Medium

TL;DR

This study provides high-precision measurements of the D/H ratio in the nearby interstellar medium, revealing spatial variability and implications for Galactic chemical evolution, using advanced modeling and high signal-to-noise data.

Contribution

The paper presents the first high-precision D/H measurements beyond the Local Bubble, confirming variability and analyzing metal depletion effects with robust error analysis.

Findings

D/H ratio varies spatially outside the Local Bubble

D/H is weakly correlated with metal depletion

Evidence suggests infalling deuterium-rich gas onto the Galactic plane

Abstract

We present high S/N measurements of the H I Ly alpha absorption line toward 16 Galactic targets which are at distances between approximately 190 and 2200 pc, all beyond the wall of the Local Bubble. We describe the models used to remove stellar emission and absorption features and the methods used to account for all known sources of error in order to compute high precision values of the H I column density with robust determinations of uncertainties. When combined with H2 column densities from other sources, we find total H column densities ranging from 10^20.01 to 10^21.25/cm2. Using deuterium column densities from FUSE observations we determine the D/H ratio along the sight lines. We confirm and strengthen the conclusion that D/H is spatially variable over these H I column density and target distance regimes, which predominantly probe the ISM outside the Local Bubble. We discuss how these results affect models of Galactic chemical evolution. We also present an analysis of metal lines along the five sight lines for which we have high resolution spectra and, along with results reported in the literature, discuss the corresponding column densities in the context of a generalized depletion analysis. We find that D/H is only weakly correlated with metal depletion and conclude that the spatial D/H variability is not solely due to dust depletion. A bifurcation of D/Htot as a function of depletion at high depletion levels provides modest support that deuterium-rich gas is infalling onto the Galactic plane.