Effect of heat flux, viscosity, and Lorentz force for the micropolar fluid flow through a stretching vertical surface

Abstract

The report on the micropolar fluid is useful in diversified areas, i.e. the flow of blood in the artery, colloidal suspension, paint, polymers, etc. The study is vital because of its exciting research and applications in different industries and science and engineering. Insight into the physical phenomena, the present article explores the character of heat flux considering the Cattaneo-Christov model on the flow of polar fluid past an expanding surface. Additionally, the conjunction of radiative hat vis-à-vis hat source enriches the thermal properties of a polar fluid. The constructive model is formulated and transformed to its non-dimensional form by the implementation of the similarity rules, and then these designed problem is handled numerically due to their complex nature. Various profiles have been studied to use diversified values of the pertinent parameters within their specified range. However, the computational results presented are well buttressed with the literature available. Moreover, the major outcomes of the results are; that the fluid velocity enhances the augmentation in the material as well as the buoyancy parameter and the inclusion of the radiative heat along with heat flux conditions favorable for the increasing fluid temperature.