Magnetohydrodynamics radiative dissipative slip flow of hydrogen-oxide (H2O) infused with various shape tungsten, tin, titanium (nanometer) particles over a nonlinear radial stretching surface

Optimal control over heat transfer during the manufacturing of various significant cylindrical components is vital to achieving a desirable finished product. Insertion of various-shaped nanoparticles provides a promising solution to the problem at hand due to their greater thermal conductivity and unique features. Keeping in view, the present article is an effort to explore the slip flow of hydrogen-oxide (H2O) infused with lamina- and column-shaped tungsten, tin, and titanium nanometer-sized particles over a nonlinear radially stretching surface. The physical model is presented by utilizing the fundamental laws of mass, momentum, and energy conservation. Magnetohydrodynamics, thermal radiation, and viscous dissipation effects are incorporated to provide physically realistic analysis. Utilizing scaling analysis flow governing problem is converted into a set of higher-order nonlinear Ordinary differential equation's which afterward are tackled numerically. Quantities of practical significance such as surface friction and heat flux are portrayed through bar graphs and are examined physically in a detailed manner. Column shape tungsten nanoparticles offered minimum surface drag with the highest heat transfer rate compared to the other two particles making them an optimal choice in manufacturing cylindrical components as per our study.