Effects of Joule Heating and Viscous Dissipation on Magnetohydrodynamic Boundary Layer Flow of Jeffrey Nanofluid over a Vertically Stretching Cylinder

This article investigates unsteady magnetohydrodynamic (MHD) mixed convective and thermally radiative Jeffrey nanofluid flow in view of a vertical stretchable cylinder with radiation absorption heat; the reservoir was addressed. The mathematical formulation is established based on theory boundary layer approximations pioneered by Prandtl. governing model expressions partial differential equations (PDEs) form transformed into dimensionless via similarity transformation technique. set nonlinear nondimensional are solved help homotopic analysis method. For purpose accuracy, optimizing system parameters, convergence, stability analytical algorithm (CSA) were performed graphically. velocity, temperature, concentration studied shown graphically effect parameters such as Grashof number, Hartman Prandtl thermal radiation, Schmidt Eckert Deborah Brownian parameter, heat source thermophoresis stretching parameter. Moreover, consequence skin friction coefficient, Nusselt Sherwood number also examined discussed.