Insights of temperature-dependent fluid characteristics on micropolar material in a rotating frame with cubic autocatalysis chemical reaction

Abstract

Abstract The diverse use of heat and mass transport mechanisms on three-dimensional rotating systems has been discovered to improve the efficiency of several physiological and industrial processes. These include, for example, fiber technology, the process of extrusion, and polymer extraction. The purpose of this dissertation is to investigate the transportation of mass and heat in the flow of non-Newtonian fluid processing vortex viscosity and micro-inertial features along two horizontal plates in a rotating scenario. The thermal transport process is influenced by physical parameters such as irregular heat generation/absorption rate, linear radiative heat flow, variable thermal conductivity, and mass diffusion with cubic autolysis chemical reaction. After enforcing conservation laws, a simple constitutive equations are modelled in a rotating system. The mathematical formulation is converted into a dimensionless format by applying comparable variables. The bvp4c process is used to execute numerical experiments to arrive at the numerical solution for the governing problem. Through sketching, the related distribution (velocity, micro rotation, velocity, and concentration) is presented concerning the various parameters. Tabular data provides insights into relevant quantities against different parameters. The credibility of computed results is assumed by agreeing with previous studies.