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Entropy generation in Casson nanofluid flow over a surface with nonlinear thermal radiation and binary chemical reaction
Author(s) -
Almakki Mohammed,
Mondal Hiranmoy,
Kameswaran Peri K.,
Sibanda Precious
Publication year - 2021
Publication title -
heat transfer
Language(s) - English
Resource type - Journals
eISSN - 2688-4542
pISSN - 2688-4534
DOI - 10.1002/htj.22106
Subject(s) - nanofluid , thermodynamics , laminar flow , reynolds number , heat transfer , boundary layer , nonlinear system , entropy (arrow of time) , thermal radiation , materials science , mechanics , physics , turbulence , quantum mechanics
We introduce a model that precisely accounts the flow of fluid of Casson nanofluid over a stretched surface with activation energy and analyze entropy generation. The model is an attempt to investigate heat transfer and entropy generation in the laminar boundary layer near a stagnation point. The modified Arrhenius function for activation energy is used. Here, the flow of the fluid is subjected to nonlinear thermal radiation, viscous disipation, binary chemical reaction, and external magnetic field. The coupled nonlinear system is further validated using the spectral lineralization method. The method is found to be accurate and convergent. The results show that the Reynolds number and Casson parameter have a significant effect in entropy generation.