MHD Flow in a Rotating Channel Surrounded in a Porous Medium with an Inclined Magnetic Field

MHD motion of a viscous incompressible electrically conducting liquid in a permeable media through a revolving channel with an inclined magnetic field is analyzed. The sheets of the channel are assumed perfectly conducting. The impact of the induced magnetic description on magnetohydrodynamic porous medium flow becomes significant by decisive importance to an inclined magnetic field. The explanation for the momentum and induced magnetic field distributions is attained in closed form. The frictional shearing stress and the rate of concentration of motion are obtained. An analysis has been made concerning a gradually revolving system once the conductivity of the liquid is small and the applied magnetic description is weak. Indeed, in a permeable medium flow, the MHD motion is generated by a Darcy number saturated by an inclined magnetic field. A literature survey reveals that none of the authors has studied such a fluid flow problem in the literature.