Transient flow of micropolar dusty hybrid nanofluid loaded with Fe3O4-Ag nanoparticles through a porous stretching sheet

A Comprehensive investigation is conducted on transient magnetohydrodynamics boundary layer flow of non-Newtonian micmpolar hybrid nanofluid (Fe3O4-Ag) immersed with conducting micrometer homogeneously sized dust nanoparticles within a stretching sheet adjacent to prescribed surface temperature (PST) and prescribed heat flux (PHF) cases is presented. The mathematical model is formulated then the convenient similarity transformations are implemented on the governing PDEs to get dimensionless system. The non-dimensional flow governing equations have been solved by help of the builtin MATLAB approach named as bvp4c which represents a finite difference method. The outcomes for variant emerging parameters for both micropolar hybrid nanofluid and dust phases are evaluated and provided throughout graphical forms, tables then argued in detail. Authentication of the gained computations is given by comparing with earlier published data. Enhancement in thermal relaxation strengthens temperature variation in both micropolar hybrid nanofluid and dust phases.

Automated summary

A comprehensive investigation on transient magnetohydrodynamics boundary layer flow of non-Newtonian micropolar hybrid nanofluid immersed with conducting micrometer homogeneously sized dust nanoparticles was conducted. The mathematical model was formulated and solved using the MATLAB approach, with outcomes for different parameters evaluated and presented graphically and in tables. Enhancement in thermal relaxation was found to strengthen temperature variation in both micropolar hybrid nanofluid and dust phases, validated by comparison with earlier published data.