Computational framework of hydrodynamic stagnation point flow of nanomaterials with natural convection configured by a heated stretching sheet

This communication studies the importance of convective heat transfer is intensified remarkably in various disciplines of modern engineering sciences and technological development such as heat exchangers, refrigeration, air conditioning, food processing, damage to crops, and many more. The main focus of this study is to develop mathematical modeling of the 2D stagnation point flow of configured by an extended heated stretchable sheet subject to nonlinear thermal radiation with the revised nanofluid model. Moreover, the influence of Newtonian heating, MHD flow, and Brownian movement features are invoked for analysis. The essential nonlinear PDEs of this assessment are modeled with the aid of boundary layer theory and then renovated into nonlinear ODEs by invoking appropriate similarity solutions with help of MATHEMATICA 11.0 programming language. The physical insight of relevant flow parameters is highlighted through graphical illustration. Finally, this investigation greatly impacts engineering and industrial applications of the materials, mainly in geophysical and geothermal systems, storage devices, space science, and several other disciplines.