Entropy generation due to micro-rotating Casson's nanofluid flow over a nonlinear stretching plate: numerical treatment

Objective: This article numerically investigates the entropy generation due to micro-rotating Casson's nanofluid along with an impact of an inclined magnetic field past a nonlinear stretching surface. Heat and mass transfer analysis is carried out in association with the heat source/sink and chemical reaction coefficient. Furthermore, heat dissipation is computed via viscous dissipation and joule heating phenomena. Attributes of nanofluid are disclosed by taking Brownian motion and thermophoresis phenomena. Results and conclusion: Numerical solutions of out-coming differential equations are obtained employing Runge-Kutta fourth-order with shooting technique. The behavior of multiple parameters has been displayed via graphs. Entropy profile is developed effectively for accelerating values of Hartmann and Brinkman number. Moreover, the temperature profile accelerates significantly with an enhancement in the heat transfer Biot number. Practice implications: The study of entropy generation due to micro-rotating Casson's nanofluid has numerous applications in engineering and heat-storing devices such as pumped heat electricity storage, phase change material, solar and geothermal power systems. The minimization of entropy plays a significant role in the design of the mechanical system that relies on heat transfer.

Automated summary

This article numerically investigates the entropy generation due to micro-rotating Casson's nanofluid with an inclined magnetic field past a nonlinear stretching surface. The study reveals the acceleration of entropy profile with increasing Hartmann and Brinkman numbers, as well as significant enhancement in temperature profile with an increase in heat transfer Biot number. The research has practical implications in engineering and heat-storing devices.