We have developed a novel Monte Carlo method for simulating the dynamical evolution of stellar systems in arbitrary geometry. The orbits of stars are followed in a smooth potential represented by a basis-set expansion and perturbed after each timestep using local velocity diffusion coefficients from the standard two-body relaxation theory. The potential and diffusion coefficients are updated after an interval of time that is a small fraction of the relaxation time, but may be longer than the dynamical time. Thus our approach is a bridge between the Spitzer’s formulation of the Monte Carlo method and the temporally smoothed self-consistent field method. The primary advantages are the ability to follow the secular evolution of shape of the st...
Context. Many astrophysical problems, ranging from structure formation in cosmology to dynamics of e...
We present an approach for simulating the collisional evolution of spherical isotropic stellar syste...
Dense stellar systems such as globular clusters, galactic nuclei and nuclear star clusters are ideal...
We have developed a novel Monte Carlo method for simulating dynamical evolution of stellar systems i...
We have recently written a new code to simulate the long term evolution of spherical clusters of st...
The evolution of dense rotating systems is studied through the use of N-body simulations. The initia...
We present a new parallel supercomputer implementation of the Monte Carlo method for simulating the ...
We present a new implementation of the Monte Carlo method to simulate the evolution of star clusters...
A revision of Stod\'o{\l}kiewicz's Monte Carlo code is used to simulate evolution of large star clus...
A stellar system being usually conceived, in a first approximation, as a group of point-like stars h...
The “gravitational million-body problem,” to model the dynamical evolution of a self-gravitating, co...
A revision of Stodolkiewicz's Monte-Carlo code is used to simulate evolution of star clusters. The n...
The main goal of our investigation is to set up a numerical laboratory for the study of the slow evo...
Context. Many astrophysical problems, ranging from structure formation in cosmology to dynamics of e...
The main goal of this paper is to set up a numerical simulation for the study of the slow evolution ...
Context. Many astrophysical problems, ranging from structure formation in cosmology to dynamics of e...
We present an approach for simulating the collisional evolution of spherical isotropic stellar syste...
Dense stellar systems such as globular clusters, galactic nuclei and nuclear star clusters are ideal...
We have developed a novel Monte Carlo method for simulating dynamical evolution of stellar systems i...
We have recently written a new code to simulate the long term evolution of spherical clusters of st...
The evolution of dense rotating systems is studied through the use of N-body simulations. The initia...
We present a new parallel supercomputer implementation of the Monte Carlo method for simulating the ...
We present a new implementation of the Monte Carlo method to simulate the evolution of star clusters...
A revision of Stod\'o{\l}kiewicz's Monte Carlo code is used to simulate evolution of large star clus...
A stellar system being usually conceived, in a first approximation, as a group of point-like stars h...
The “gravitational million-body problem,” to model the dynamical evolution of a self-gravitating, co...
A revision of Stodolkiewicz's Monte-Carlo code is used to simulate evolution of star clusters. The n...
The main goal of our investigation is to set up a numerical laboratory for the study of the slow evo...
Context. Many astrophysical problems, ranging from structure formation in cosmology to dynamics of e...
The main goal of this paper is to set up a numerical simulation for the study of the slow evolution ...
Context. Many astrophysical problems, ranging from structure formation in cosmology to dynamics of e...
We present an approach for simulating the collisional evolution of spherical isotropic stellar syste...
Dense stellar systems such as globular clusters, galactic nuclei and nuclear star clusters are ideal...