Melting Heat Transfer Rheology in Bioconvection Cross Nanofluid Flow Confined by a Symmetrical Cylindrical Channel with Thermal Conductivity and Swimming Microbes

Nonlinear thermal transport of non-Newtonian polymer flows is an increasingly important area in materials engineering. Motivated by new developments this which entail more refined and mathematical frameworks, the present analysis investigates boundary-layer approximation heat transfer persuaded a symmetrical cylindrical surface positioned horizontally. To simulate relaxation impacts, bioconvection Cross nanofluid flow Buongiorno model deployed. The study examines magnetic field effect applied to using generated, as well melting phenomenon. nonlinear thermosolutal buoyant forces incorporated into proposed model. novel equations include thermophoresis Brownian diffusion effects. Via robust transformation techniques, primitive resulting partial for momentum, energy, concentration, motile living microorganisms are rendered ordinary with convective boundary postulates. An explicit efficient numerical solver procedure Mathematica 11.0 programming platform developed engage equations. effects multiple governing parameters on dimensionless fluid profiles examined plotted visuals tables. Finally, outcomes related drag force, heat, mass coefficients different influential presented 3D visuals.