A mathematical analysis of the unsteady magnetohydrodynamic stagnation point flow of a nanofluid consisting of single-walled carbon nanotubes and human blood through a stretchable wall with slip effects

In this study, we examine the boundary layer flow of magnetohydrodynamic single-wall carbon nanotubes combined with human blood as the base fluid approaching a stretchable surface. Nonlinear governing equations turned into nonlinear ordinary differential equations by employing some similarity conversions and the resulting equations with associated boundary conditions are solved numerically by applying the perturbation technique. Profiles of velocity and temperature as well as shear stress and heat flux at the wall under the influence of several controlling parameters are examined in detail and the results are represented in graphical and tabular forms. Results show how these variables are influenced by various controlling parameters, demonstrating the intricate interplay between nanotube, magnetic field strength and fluid properties. A correlation with the earlier published data is also shown to validate the results and a brilliant concurrence can be seen, and so reliable results are being introduced. The outcomes of our model provide a foundation for designing efficient drug delivery systems and biomagnetic applications. The understanding of how nanotubes interact with blood flow under magnetic fields can lead to improved strategies for manipulating and guiding nanoparticles within the body, enhancing the precision of medical interventions.