Generalized slip impact of Casson nanofluid through cylinder implanted in swimming gyrotactic microorganisms

In this paper, the self-propelled movement on gyrotactic swimming microorganisms into this generalized slip flow by nanoliquid over the stretching cylinder with strong magnetic field is discussed. Constant wall temperature was pretended as well as the Nield conditions of boundary. The intuitive non-Newtonian particulate suspension was included into applying Casson fluid by the base liquid and nanoparticles. This formation on the bio-mathematical model gives the boundary value problem by the nonlinear partial differential equations. Primly, modeled numerical system was converted to nondimensional against this help on acceptable scaling variables and the bvp4c technique was used to acquire the mathematical outcomes on the governing system. This graphical description by significant parameters and their physical performance was widely studied. The Prandtl number has the maximum contribution (112.595%) along the selected physical parameters, whereas the Brownian motion has the least (0.00165%) heat transfer rate. Anyhow, Casson fluid was established for much helpful suspension of this method on fabrication and coatings, etc. Therefore, this magnetic field performs like the resistive force of that fluid motion, and higher energy was enlarged into the structure exhibiting strong thermal radiation.

Automated summary

This paper discusses the slip flow of self-propelled gyrotactic swimming microorganisms on a stretching cylinder with a strong magnetic field using nanoliquid. The study shows that the Prandtl number has the most significant contribution to the physical parameters, while the heat transfer rate of Brownian motion is the least. Casson fluid is found to be helpful in suspension for methods such as fabrication and coatings.