We have studied head-on collisions between equal-mass, mildly supersonic H I clouds (Mach number 1.5 with respect to the background medium) through high-resolution numerical simulations in two dimensions. We explore the role of various factors, including the radiative cooling parameter, eta = tau(rad)/tau(coll) (tau(coll) = R-c/upsilon(c)), evolutionary modifications on the cloud structure, and the symmetry of the problem. Self-gravity is not included. Radiative losses are taken into account explicitly and not approximated with an isothermal adiabatic index gamma approximate to 1, which, in fact, leads to very different results. We assume a standard two-phase interstellar medium (ISM) model where clouds are characterized by a temperature T-...
The effect of smooth cloud boundaries on the interaction of steady planar shock waves with interstel...
Context. The complexity of the interstellar medium (ISM) is such that it is unlikely that star forma...
We simulate the collapse of a turbulent gas cloud with the particle-based code Gadget2. We choose tw...
We extend previous studies of the physics of interstellar cloud collisions by beginning an investiga...
We investigate cloud–cloud collisions and giant molecular cloud evolution in hydrodynamic simulation...
We investigate cloud-cloud collisions, and GMC evolution, in hydrodynamic simulations of isolated ga...
We present 2D adiabatic magnetohydrodynamic simulations of a shock interacting with groups of two or...
We explore the survival of cool clouds in multiphase circumgalactic media. We revisit the ‘cloud-cru...
We present 3D hydrodynamic simulations of the adiabatic interaction of a shock with a dense, spheric...
We model the hydrodynamic interaction of a shock wave of an evolved supernova remnant with a small i...
We present the results of smoothed particle hydrodynamics simulations in which two clouds, each havi...
The interaction of a hot, high-velocity wind with a cold, dense molecular cloud has often been assum...
The galactic disk is largely composed of hot, rarefied gas also called the inter cloud medium (ICM)....
The similarities, or otherwise, of a shock or wind interacting with a cloud of density contrast χ = ...
Recent numerical simulations of the interstellar medium driven by energy input from supernovae and s...
The effect of smooth cloud boundaries on the interaction of steady planar shock waves with interstel...
Context. The complexity of the interstellar medium (ISM) is such that it is unlikely that star forma...
We simulate the collapse of a turbulent gas cloud with the particle-based code Gadget2. We choose tw...
We extend previous studies of the physics of interstellar cloud collisions by beginning an investiga...
We investigate cloud–cloud collisions and giant molecular cloud evolution in hydrodynamic simulation...
We investigate cloud-cloud collisions, and GMC evolution, in hydrodynamic simulations of isolated ga...
We present 2D adiabatic magnetohydrodynamic simulations of a shock interacting with groups of two or...
We explore the survival of cool clouds in multiphase circumgalactic media. We revisit the ‘cloud-cru...
We present 3D hydrodynamic simulations of the adiabatic interaction of a shock with a dense, spheric...
We model the hydrodynamic interaction of a shock wave of an evolved supernova remnant with a small i...
We present the results of smoothed particle hydrodynamics simulations in which two clouds, each havi...
The interaction of a hot, high-velocity wind with a cold, dense molecular cloud has often been assum...
The galactic disk is largely composed of hot, rarefied gas also called the inter cloud medium (ICM)....
The similarities, or otherwise, of a shock or wind interacting with a cloud of density contrast χ = ...
Recent numerical simulations of the interstellar medium driven by energy input from supernovae and s...
The effect of smooth cloud boundaries on the interaction of steady planar shock waves with interstel...
Context. The complexity of the interstellar medium (ISM) is such that it is unlikely that star forma...
We simulate the collapse of a turbulent gas cloud with the particle-based code Gadget2. We choose tw...