%0 Journal Article %A Kumar, Rakesh %A Shehzad, Sabir Ali %A Bashir, M. N. %D 2020 %I Begell House %K vibrational rotations, velocity slip, radiative heat transfer, iron-oxide nanoparticles, porous medium %N 9 %P 865-881 %R 10.1615/JPorMedia.2020024935 %T NUMERICAL SIMULATION OF THREE-DIMENSIONAL FLOW OF RADIATING GRAY NANOFLUID THROUGH POROUS MEDIUM SUBJECTED TO VIBRATIONAL ROTATIONS AND SLIP AT LIQUID-SHEET INTERFACE %U https://www.dl.begellhouse.com/journals/49dcde6d4c0809db,1350cb5d0e1bb84d,6a2dff9d5c36463a.html %V 23 %X We present a numerical scheme based on explicit finite difference approximation to handle the three-dimensional boundary layer flow of absorbing, emitting, and electrically conducting grey nanofluid over a flat surface. Nanofluid is designed by suspending iron-oxide nanoparticles (IONPs) in the base fluid. The flow field is assumed to be embedded in the porous medium, which executes vibrational rotations. To maintain the flow, velocity slip is introduced at the liquid-sheet interface. The governing equations are reduced to nondimensional form using dimensionless parameters and variables. The stability and convergence criteria have also been discussed to elaborate the validity of results. The hydromagnetic and convective heat transfer characteristics of magnetite nanofluid have been exhibited through graphs and tables for different related parameters. Substantial influences of oscillations and rotations have been noticed on the velocity profiles, temperature profiles, skin-friction coefficients, and Nusselt number. %8 2020-08-05