Direct numerical simulations (DNS) of spanwise-rotating turbulent channel flow were conducted. The data base obtained from these DNS simulations were used to investigate the turbulence generation cycle for simple and complex turbulence. For turbulent channel flow, three theoretical models concerning the formation and evolution of sublayer streaks, three-dimensional hairpin vortices and propagating plane waves were validated using visualizations from the present DNS data. The principal orthogonal decomposition (POD) method was used to verify the existence of the propagating plane waves; a new extension of the POD method was derived to demonstrate these plane waves in a spatial channel model. The analyses of coherent structures was extended t...
A direct numerical simulation of a fully developed turbulent channel flow with passive heat transfer...
Direct numerical simulations (DNS) and large-eddy simulations (LES) of a turbulent channel flow with...
© 2009 Cambridge University Press. Online edition of the journal is available at http://journals.cam...
A direct numerical simulation (DNS) of a spanwise-rotating turbulent channel flow was conducted for ...
Nearly all moving objects on Earth pass through fluids and many of them move at high speed. This mak...
Abstract — In this contribution a study of a turbulent channel flow rotating about the streamwise di...
Direct numerical simulation (DNS) databases are compared to assess the accuracy and reproducibility ...
Direct Numerical Simulations (DNS) provide an increasing data source to improve our understanding of...
Heat transfer is studied in fully-developed turbulent flows through channels with various geometries...
The flow of a viscous fluid in a plane channel is simulated numerically following the DNS approach, ...
Different aspects of numerical simulations of turbulent flows are assessed by considering a fully-de...
A computer code has been developed to predict three-dimensional incompressible turbulent flow in com...
This contribution is concerned with the simulation of turbulent shear flows. First, direct numerical...
Direct numerical simulation (DNS) databases are compared to assess the accuracy and reproducibility ...
Three types of turbulence models which account for rotational effects in noninertial frames of refer...
A direct numerical simulation of a fully developed turbulent channel flow with passive heat transfer...
Direct numerical simulations (DNS) and large-eddy simulations (LES) of a turbulent channel flow with...
© 2009 Cambridge University Press. Online edition of the journal is available at http://journals.cam...
A direct numerical simulation (DNS) of a spanwise-rotating turbulent channel flow was conducted for ...
Nearly all moving objects on Earth pass through fluids and many of them move at high speed. This mak...
Abstract — In this contribution a study of a turbulent channel flow rotating about the streamwise di...
Direct numerical simulation (DNS) databases are compared to assess the accuracy and reproducibility ...
Direct Numerical Simulations (DNS) provide an increasing data source to improve our understanding of...
Heat transfer is studied in fully-developed turbulent flows through channels with various geometries...
The flow of a viscous fluid in a plane channel is simulated numerically following the DNS approach, ...
Different aspects of numerical simulations of turbulent flows are assessed by considering a fully-de...
A computer code has been developed to predict three-dimensional incompressible turbulent flow in com...
This contribution is concerned with the simulation of turbulent shear flows. First, direct numerical...
Direct numerical simulation (DNS) databases are compared to assess the accuracy and reproducibility ...
Three types of turbulence models which account for rotational effects in noninertial frames of refer...
A direct numerical simulation of a fully developed turbulent channel flow with passive heat transfer...
Direct numerical simulations (DNS) and large-eddy simulations (LES) of a turbulent channel flow with...
© 2009 Cambridge University Press. Online edition of the journal is available at http://journals.cam...