Nanofluid bioconvective transport for non-Newtonian material in bidirectional oscillating regime with nonlinear radiation and external heat source: Applications to storage and renewable energy

Abstract

The enhanced thermal performances of nanofluids reports different applications in solar systems energy storage and renewable energy. The renewable enhancement in thermal management systems is predicted in recent years. Following such motivations of nanomaterials in the renewable systems, the objective of current wok is to present nanofluid flow with suspension of non-Newtonian material with additional impact of external heating source. The Williamson nanofluid is signifies to suggests the rheological impact of nonlinear material. The stability of nanofluid is reported with bioconvection assessment due to microorganisms. The thermal model is further modified in view of nonlinear radiative electromagnetic source and activation energy. Time dependent flow is induced due to bidirectional accelerating surface with uniform magnitude. The formulation of problem is based in partial differential systems. The solution procedure is based on analytical homotopy analysis technique. The thermal outcomes in variation of parameters are observed. It is claimed that external heat presentation can boosted the thermal profile more exclusively. With increasing the Williamson fluid parameter, the heat and mass transfer phenomenon can be improved.