To date, most numerical simulations of molecular clouds, and star formation within them, assume a uniform density sphere or box with an imposed turbulent velocity field. In this work, we select molecular clouds from galactic scale simulations as ini-tial conditions, increase their resolution, and re-simulate them using the SPH code Gadget2. Our approach provides clouds with morphologies, internal structures, and kinematics that constitute more consistent and realistic initial conditions for simula-tions of star formation. We perform comparisons between molecular clouds derived from a galactic simulation, and spheres of turbulent gas of similar dimensions, mass and velocity dispersion. We focus on properties of the clouds such as their densi...
We examine the physical parameters that affect the accumulation of gas in molecular clouds to high c...
We examine the formation of bound coherent clumps within the environment of turbulent molecular clou...
I present a new suite of simulations that resolve individual molecular clouds down to ~0.1 pc scales...
To date, most numerical simulations of molecular clouds, and star formation within them, assume a un...
We present the results of a numerical simulation in which star formation proceeds from an initially ...
We study the formation of giant dense cloud complexes and of stars within them using SPH numerical s...
The formation of stars remains an outstanding unsolved problem in astrophysics. Central to this pro...
Young massive clusters (YMCs) are recently formed astronomical objects with unusually high star form...
Molecular clouds (MCs) are highly structured and turbulent. Colliding gas streams of atomic hydrogen...
Prestellar Cores are created by the interaction of a turbulent velocity field and gravity. On large...
Abstract. Star formation is one of the least understood processes in cosmic evolution. It is difficu...
Trying to understand the formation of molecular clouds (MCs) and the generation of non-thermal motio...
As part of a series of papers aimed at understanding the evolution of the Milky Way's Central Molecu...
We review the properties of turbulent molecular clouds (MCs), focusing on the physical processes tha...
We studied the formation of stars from colliding molecular clouds by performing smoothed particle h...
We examine the physical parameters that affect the accumulation of gas in molecular clouds to high c...
We examine the formation of bound coherent clumps within the environment of turbulent molecular clou...
I present a new suite of simulations that resolve individual molecular clouds down to ~0.1 pc scales...
To date, most numerical simulations of molecular clouds, and star formation within them, assume a un...
We present the results of a numerical simulation in which star formation proceeds from an initially ...
We study the formation of giant dense cloud complexes and of stars within them using SPH numerical s...
The formation of stars remains an outstanding unsolved problem in astrophysics. Central to this pro...
Young massive clusters (YMCs) are recently formed astronomical objects with unusually high star form...
Molecular clouds (MCs) are highly structured and turbulent. Colliding gas streams of atomic hydrogen...
Prestellar Cores are created by the interaction of a turbulent velocity field and gravity. On large...
Abstract. Star formation is one of the least understood processes in cosmic evolution. It is difficu...
Trying to understand the formation of molecular clouds (MCs) and the generation of non-thermal motio...
As part of a series of papers aimed at understanding the evolution of the Milky Way's Central Molecu...
We review the properties of turbulent molecular clouds (MCs), focusing on the physical processes tha...
We studied the formation of stars from colliding molecular clouds by performing smoothed particle h...
We examine the physical parameters that affect the accumulation of gas in molecular clouds to high c...
We examine the formation of bound coherent clumps within the environment of turbulent molecular clou...
I present a new suite of simulations that resolve individual molecular clouds down to ~0.1 pc scales...