We present a novel framework to self-consistently model the effects of radiation fields, dust physics, and molecular chemistry (H2) in the interstellar medium (ISM) of galaxies. The model combines a state-of-the-art radiation hydrodynamics module with a H and He non-equilibrium thermochemistry module that accounts for H2 coupled to an empirical dust formation and destruction model, all integrated into the new stellar feedback framework SMUGGLE. We test this model on high-resolution isolated Milky-Way (MW) simulations. We show that the effect of radiation feedback on galactic star formation rates is quite modest in low gas surface density galaxies like the MW. The multiphase structure of the ISM, however, is highly dependent on the strength ...
To understand the conditions under which dense, molecular gas is able to form within a galaxy, we po...
We present an efficient heating/cooling method coupled with chemistry and ultraviolet (UV) radiative...
We study the connection of star formation to atomic (H I) and molecular hydrogen (H2) in isolated, l...
We present a novel framework to self-consistently model the effects of radiation fields, dust physic...
Interstellar chemistry is important for galaxy formation, as it determines the rate at which gas can...
Aims: We present and test chemical models for three-dimensional hydrodynamical simulations of galaxi...
This article has been accepted for publication in Monthly Notices of the Royal Astronomical Society ...
We present high-resolution hydrodynamical simulations of isolated dwarf galaxies including self-grav...
We introduce the Stars and MUltiphase Gas in GaLaxiEs - SMUGGLE model, an explicit and comprehensive...
We introduce a dust model for cosmological simulations implemented in the moving-mesh code AREPO and...
Nearby dwarf irregular galaxies are ideal laboratories for studying the interstellar medium (ISM) at...
We present a series of hydrodynamic simulations of isolated galaxies with stellar mass of 109M˙. The...
To understand the conditions under which dense, molecular gas is able to form within a galaxy, we po...
We present an efficient heating/cooling method coupled with chemistry and ultraviolet (UV) radiative...
We study the connection of star formation to atomic (H I) and molecular hydrogen (H2) in isolated, l...
We present a novel framework to self-consistently model the effects of radiation fields, dust physic...
Interstellar chemistry is important for galaxy formation, as it determines the rate at which gas can...
Aims: We present and test chemical models for three-dimensional hydrodynamical simulations of galaxi...
This article has been accepted for publication in Monthly Notices of the Royal Astronomical Society ...
We present high-resolution hydrodynamical simulations of isolated dwarf galaxies including self-grav...
We introduce the Stars and MUltiphase Gas in GaLaxiEs - SMUGGLE model, an explicit and comprehensive...
We introduce a dust model for cosmological simulations implemented in the moving-mesh code AREPO and...
Nearby dwarf irregular galaxies are ideal laboratories for studying the interstellar medium (ISM) at...
We present a series of hydrodynamic simulations of isolated galaxies with stellar mass of 109M˙. The...
To understand the conditions under which dense, molecular gas is able to form within a galaxy, we po...
We present an efficient heating/cooling method coupled with chemistry and ultraviolet (UV) radiative...
We study the connection of star formation to atomic (H I) and molecular hydrogen (H2) in isolated, l...