Upscaling of elastic properties for large scale geomechanical simulations

We present a set of numerical methods for simulations of microstructural evolution in elastically stressed solids. We combine three powerful tools to achieve computational efficiency: the boundary integral method to provide excellent resolution, the fast multipole method to reduce computational cost

An efficient numerical method for simulating the motion of a large number of spherical bubbles through an inviscid liquid is described. The flow induced by each bubble is approximated as that due to a monopole and a dipole, and a rapid summation method based on dividing the system into groups of bub

This paper is aimed at introducing computer simulation of extended defects in crystalline materials by means of empirical potentials. In this context we understand by large scale calculations those related to a number of atoms from 10 3 to 10 6 and/or a time scale of few nanoseconds (10 2 -10 4 ps)

## Abstract Red blood cells (RBCs) are an essential component of blood. A method to include the particulate nature of blood is introduced here with the goal of studying circulation in large‐scale realistic vessels. The method uses a combination of the Lattice Boltzmann method (LBM) to account for t

tasks, which results in considerable CPU time savings. This method is based on selectively limiting the calculation of A method of optimizing molecular dynamics calculations is presented. The method employs multiple time steps across the computhe forces and the neighbor list updating, according to t