Inclined magnetic field and joule heat on unsteady ternary nanofluidic flow impinging over a convectively heated cylinder

Abstract

The present analysis considered the condition of unsteady stagnation point flow on ternary nanofluid [Formula: see text] through the regularly affecting and convective heated stretchable cylinder by the effect on inclining Lorentz force. This influence on thermal radiation, velocity slip, viscous dissipation, and Joule dissipation were again integrated by the analysis. The suitable thermo-physical relationship in the hybrid nanofluid is cultivated into followed Xue form. With the help of appropriate comparison alterations, the controlling dimensional numerical equations were transformed by the dimensionless models. The governing equations are transformed through comparison transformation and mathematically tackled in MATLAB with a boundary value problem algorithm. These mathematical solutions were validated with the presented material. Tabular and graphical descriptions of mathematical information were utilized to analyze the physical effect on different relevant parameters in the ternary nanofluid temperature and velocity. This thermal buoyancy force hikes the fluid flow although the opposite direction was noted in magnetic parameters and velocity slips. This heat transport rate in the surface was enhanced by an improvement in thermal radiation, Biot number, and solid fraction of nanoparticles. Moreover, a 44.9754% enhanced decreased skin friction is observed by triple nanoparticle nanofluid it signifies its best behavior as related to both other nanofluids.