Spatial-Kinematic Absorption Models of the Circumgalactic Medium. I. Structures, Orientations, and Kinematics

TL;DR

This paper introduces a flexible mathematical framework for modeling the spatial and kinematic structures of the circumgalactic medium to interpret quasar absorption line observations.

Contribution

It develops idealized geometries and velocity fields of the CGM, enabling tailored simulations of absorption profiles for various galaxy environments.

Findings

Four idealized galaxy/CGM structures modeled

Expressions derived for observer's perceived angles and velocities

Framework adaptable for real observations and simulations

Abstract

In this two-paper series, we present a straightforward mathematical model for synthesizing quasar absorption line profiles from sight lines through idealized, spatial-kinematic models of the circumgalactic medium (CGM) and their host galaxies. Here, in Paper I, we develop the spatial geometries of multiple galaxy/CGM structures and populate these structures with 3D velocity fields. For arbitrary viewing angles and galaxy-quasar impact parameters, we derive observer coordinate-based expressions for the perceived azimuthal angle and galaxy inclination and a generalized scalar expression for the line-of-sight velocity as a function of position along the line of sight. We motivate and develop four idealized galaxy/CGM spatial-kinematic structures based on empirical data and theoretical predictions: (1) a rotating galactic disk/extra-planar gas, (2) a static or dynamic spherical halo, (3) an outflowing bi-polar galactic wind, and (4) an inward spiraling flared planar accretion. Using a small set of free parameters, the spatial geometries and velocity fields can be adjusted and explored, including velocity gradients, wind stalling, and accretion trajectories. These spatial-kinematic models are designed to be flexible and easily modified and can be tailored for studying individual galaxy-absorber pairs or galaxy group environments; they can be applied to real-world observations or hydrodynamic simulations of the baryon cycle as studied through quasar absorption line systems. These models also serve as tools for developing physical intuition. In Paper II, we will present the formalism for populating the galaxy/CGM structures with multiphase photoionized and collisionally ionized gas and for generating absorption profiles for ions of interest.