Numerical simulations of compressibility effects in free-surface flow resulting from wave impacts on an idealized seawall.

In this paper, we show how the classical Monte Carlo method can be used to tackle both the global optimization problem of molecular structure and the finite temperature

A modeling of the effective plastic flow surface following [1] is briefly recalled and the results are compared to original numerical simulations using a computa- tional method based

For strong SWBLIs, it is well established that the separation bubble and the system of shock waves (included the reflected shock wave whose foot is located upstream from the

Numerical models based on the Boundary Element Method (BEM), combined to an explicit higher-order Lagrangian time stepping, have proved very efficient and accurate for solving

At large Reynolds number, the molecular dissipation in the balance equation of the turbulent heat flux becomes negligible away from the wall (Pope 2000). Extrapolating the

It has been compared to more rigorous numerical site response analyses based on a sophisticated soil constitutive model from which the ground surface acceleration has been found

We first briefly report here (Sec. 2) on experimen- tal measurements on pressure-dependent sound veloc- ities and attenuation in dense samples of dry glass beads (hereafter denoted

The patterns of differences between the mod and the non-oasis simulations show that there is indeed a remarkable difference in specific humidity over the oasis areas during