Multiscale Turbulent Transport
Afonso, Marco Martins
Multiscale Turbulent Transport - MDPI - Multidisciplinary Digital Publishing Institute 2020 - 1 electronic resource (210 p.)
Open Access
Turbulent transport is currently a prominent and ongoing investigation subject at the interface of methodologies from theory to numerical simulations and experiments, and it covers several spatiotemporal scales. Mathematical analysis, physical modelling, and engineering applications represent different facets of a classical, long-standing problem that is still far from being thoroughly comprehended. The goal of this Special Issue is to outline recent advances of such subjects as multiscale analysis in turbulent transport processes, Lagrangian and Eulerian descriptions of turbulence, advection of particles and fields in turbulent flows, ideal or nonideal turbulence (unstationary/inhomogeneous/anisotropic/compressible), turbulent flows in biofluid mechanics and magnetohydrodynamics, and the control and optimization of turbulent transport. The SI is open to regular articles, review papers focused on the state of the art and the progress made over the last few years, and new research trends.
Creative Commons
English
books978-3-03928-213-5 9783039282135 9783039282128
10.3390/books978-3-03928-213-5 doi
weak turbulence chaotic advection n/a channel flow Direct Numerical Simulation (DNS) recirculation bubble Euler equations relaxation filtering incompressible fluid Runge–Kutta (RK4) wall-resolved Large Eddy Simulation (LES) 3D perturbations of 2D steady base flow OpenFOAM separation and reattachment compressible flow cascade turbulence models turbulence intermittency WENO schemes PISO time-dependent diffusion coefficient magnetic mode multiscale variable density flow transient evolution nematic electroconvection direct numerical simulation Navier–Stokes equations (RANS) energy transfer alpha-effect linear stability analysis warm cloud top mixing eddy viscosity Rayleigh–Bènard convection baroclinic vortex generation eddy diffusivity turbulence theory cloud micro-physics structural sensitivity droplets optimal control Lagrangian chaos streak lift-up incompressibility breakage model turbulent-wake and Kelvin–Helmholtz instabilities defect turbulence Rayleigh–Taylor instability Padé approximant 25° backward-slanted step implicit LES
Multiscale Turbulent Transport - MDPI - Multidisciplinary Digital Publishing Institute 2020 - 1 electronic resource (210 p.)
Open Access
Turbulent transport is currently a prominent and ongoing investigation subject at the interface of methodologies from theory to numerical simulations and experiments, and it covers several spatiotemporal scales. Mathematical analysis, physical modelling, and engineering applications represent different facets of a classical, long-standing problem that is still far from being thoroughly comprehended. The goal of this Special Issue is to outline recent advances of such subjects as multiscale analysis in turbulent transport processes, Lagrangian and Eulerian descriptions of turbulence, advection of particles and fields in turbulent flows, ideal or nonideal turbulence (unstationary/inhomogeneous/anisotropic/compressible), turbulent flows in biofluid mechanics and magnetohydrodynamics, and the control and optimization of turbulent transport. The SI is open to regular articles, review papers focused on the state of the art and the progress made over the last few years, and new research trends.
Creative Commons
English
books978-3-03928-213-5 9783039282135 9783039282128
10.3390/books978-3-03928-213-5 doi
weak turbulence chaotic advection n/a channel flow Direct Numerical Simulation (DNS) recirculation bubble Euler equations relaxation filtering incompressible fluid Runge–Kutta (RK4) wall-resolved Large Eddy Simulation (LES) 3D perturbations of 2D steady base flow OpenFOAM separation and reattachment compressible flow cascade turbulence models turbulence intermittency WENO schemes PISO time-dependent diffusion coefficient magnetic mode multiscale variable density flow transient evolution nematic electroconvection direct numerical simulation Navier–Stokes equations (RANS) energy transfer alpha-effect linear stability analysis warm cloud top mixing eddy viscosity Rayleigh–Bènard convection baroclinic vortex generation eddy diffusivity turbulence theory cloud micro-physics structural sensitivity droplets optimal control Lagrangian chaos streak lift-up incompressibility breakage model turbulent-wake and Kelvin–Helmholtz instabilities defect turbulence Rayleigh–Taylor instability Padé approximant 25° backward-slanted step implicit LES