Computational Framework on MHD Hybrid Nanofluid Flow Over A Stretching Surface with Thermal Radiation

Nanofluids improve heat transmission in a variety of sectors, including automotive production, medical care, solar power, and technology. In the presence of a magnetic field, a comparative examination of hybrid nanofluids is investigated. Porous media and heat radiation are the new issues that are being investigated in the present study. Thermal energy serves as the foundation of motivation for hybrid nanofluid delivery, which is discussed in this article. By applying the compatible similarity functions, the higher-order PDEs are renewed into a couple of ordinary differential equations. The MATLAB platform via bvp5c code is used for numerical technique. A trustworthy comparison with previously published literature is carried out in order to ensure the correctness and validity of the findings. The graphical results for various profiles, such as velocity and energy, are shown for various important active parameters. It is perceived that by increasing the magnetic parameters M and Pr, the velocity and temperature of the fluid decrease, respectively. Specifically, the results of this work contribute to the advancement of understanding in the field of MHD as well as heat transfer mechanisms. Furthermore, the learnings that were obtained have the ability to improve the effectiveness and performance of thermodynamic systems across different kinds of applications, including those in the industrial and medical fields.