Nanoscale heat and mass transport of magnetized 3-D chemically radiative hybrid nanofluid with orthogonal/inclined magnetic field along rotating sheet

This work is related to the chemical process in nanomaterial that has prominent applications in water-solubility, octanol-water partition coefficient, melting points, vapor pressure and various astonishing features. Nanoparticles have unique chemical effects in the field of nanoscience and nanotechnology. This study determines the impacts of homogeneous heterogeneous reactions along with nanoscale heat transport of inclined magnetized three-dimensional (3-D) water-based Hybrid nanofluid. The geometry of rotating and shrinking/stretching sheet with the effects of thermal radiation is also presented. Nanoparticles of aluminum oxide and silver are being used with water as base fluid. Mathematical model of Hybrid nanofluid generates the set of partial differential equation (PDEs) and these are transmuted into ordinary differential equations (ODEs) by using the similarity of variables. MATLAB built-in bvp4c procedures are implemented to find the numerical solutions. Moreover, physical descriptions of current study are revealed out through graphs and tables. Statistical analysis of physical quantities is presented in the form of bar graphs to show the regulating parameter effects.

Automated summary

This study investigates the chemical process in nanomaterials and its applications, such as water-solubility, octanol-water partition coefficient, melting points, and vapor pressure. The impacts of homogeneous heterogeneous reactions and nanoscale heat transport in inclined magnetized 3-D water-based Hybrid nanofluid are determined. The physical quantities are analyzed through mathematical models, numerical solutions, and statistical analysis presented in graphs and tables.