Revealing the Milky Way's Hidden Circumgalactic Medium with the Cosmic Origins Spectrograph Quasar Database for Galactic Absorption Lines

TL;DR

This study analyzes Hubble COS spectra of 132 quasars to uncover hidden gas in the Milky Way's circumgalactic medium, revealing a significant amount of low-velocity gas and proposing a two-component model for its distribution.

Contribution

The paper introduces a new two-component model for the Milky Way's circumgalactic medium based on a large quasar absorption line dataset, providing insights into the gas distribution and mass.

Findings

Detection of significant SiIV absorption at low velocities in the Galactic halo.

Proposal of a two-component model explaining the SiIV distribution with a disk-halo and a global component.

Estimate of the total cool gas mass in the Milky Way's CGM exceeding 4.7×10^9 solar masses.

Abstract

Every quasar (QSO) spectrum contains absorption-line signatures from the interstellar medium, disk-halo interface, and circumgalactic medium (CGM) of the Milky Way (MW). We analyze Hubble Space Telescope/Cosmic Origins Spectrograph (COS) spectra of 132 QSOs to study the significance and origin of SiIV absorption at $|v_{\rm LSR}|\leq100$ km/s in the Galactic halo. The gas in the north predominantly falls in at $-50\lesssim v_{\rm LSR}\lesssim 0$ km/s, whereas in the south, no such pattern is observed. The SiIV column density has an average and a standard deviation of $\langle N_{\rm SiIV}\rangle=(3.8\pm1.4)\times10^{13}$ cm$^{-2}$. At $|b|\gtrsim 30$ degree, $N_{\rm SiIV}$ does not significantly correlate with $b$, which cannot be explained by a commonly adopted flat-slab geometry. We propose a two-component model to reconstruct the $N_{\rm SiIV}$-$b$ distribution: a plane-parallel component $N_{\rm DH}^{\perp}$ to account for the MW's disk-halo interface and a global component $N_{\rm G}$ to reproduce the weak dependence on $b$. We find $N_{\rm DH}^{\perp}=1.3^{+4.7}_{-0.7}\times10^{12}$ cm$^{-2}$ and $N_{\rm G}=(3.4\pm0.3)\times10^{13}$ cm$^{-2}$ on the basis of Bayesian analyses and block bootstrapping. The global component is most likely to have a Galactic origin, although its exact location is uncertain. If it were associated with the MW's CGM, we would find $M_{\rm gas, all}\gtrsim4.7\times10^9\ M_{\odot} (\frac{C_f}{1})(\frac{R}{75\ {\rm kpc}})^2 (\frac{f_{\rm SiIV}}{0.3})^{-1}(\frac{Z}{0.3\ Z_{\odot}})^{-1}$ for the cool gas at all velocities in the Galactic halo. Our analyses show that there is likely a considerable amount of gas at $|v_{\rm LSR}|\leq100$ km s$^{-1}$ hidden in the MW's CGM. Along with this work, we make our QSO dataset publicly available as the COS Quasar Database for Galactic Absorption Lines (COS-GAL).