High strain Lagrangian hydrodynamics: a three-dimensional SPH code for dynamic material response
Journal of Computational Physics
Simulating free surface flows with SPH
Journal of Computational Physics
Smoothed particle hydrodynamics stability analysis
Journal of Computational Physics
Modeling low Reynolds number incompressible flows using SPH
Journal of Computational Physics
Conduction modelling using smoothed particle hydrodynamics
Journal of Computational Physics
SPH without a tensile instability
Journal of Computational Physics
SPH simulation of river ice dynamics
Journal of Computational Physics
Simulation of pore-scale dispersion in periodic porous media using smoothed particle hydrodynamics
Journal of Computational Physics
Remeshed smoothed particle hydrodynamics for the simulation of viscous and heat conducting flows
Journal of Computational Physics
Constructing smoothing functions in smoothed particle hydrodynamics with applications
Journal of Computational and Applied Mathematics
Statistical prediction of laminar-turbulent transition
Statistical prediction of laminar-turbulent transition
Remeshed smoothed particle hydrodynamics for the simulation of laminar chemically reactive flows
Journal of Computational Physics
Numerical simulation of interfacial flows by smoothed particle hydrodynamics
Journal of Computational Physics
SPH simulations of time-dependent Poiseuille flow at low Reynolds numbers
Journal of Computational Physics
Remeshed smoothed particle hydrodynamics simulation of the mechanical behavior of human organs
Technology and Health Care
| Hi-index | 31.45 |
Active flow control of electrically conducting fluids finds growing importance in the metallurgical industry. A magnetic field applied in the streamwise direction of electrically conducting fluid flow restrains the velocity fluctuations in the transverse plane and the transition to turbulence may be delayed. The smoothed particle hydrodynamic (SPH) methodology is employed to interpret this concept. To this purpose, the onset of turbulence is related to the transitional organization of the SPH fluid particle structure or to the temporal history of the turbulence-related quantities during the early stages of the transition to turbulence. The results put in evidence the ability of a streamwise magnetic field on controlling the transition to turbulence of an electrically conducting fluid flow, i.e., the transition to turbulence may be distinctly delayed in the fluid flow subjected to a streamwise magnetic field. Furthermore, if the applied streamwise magnetic field is strong enough, the Reynolds stress in the streamwise direction may be dominant over the transverse counterpart, and turbulence is anisotropic as only in the streamwise direction of the fluid flow, the Reynolds stress is detectable.