Abstract
The current continuation aim is to explore the rheological consequences of Eyring Powell nanofluid over a moving surface in the presence of activation energy and thermal radiation. The bioconvection of magnetized nanoparticles is executed with the evaluation of motile microorganism. The most interesting Wu’s slip effects are also assumed near the surface. The evaluation of nanoparticles for current flow problems has been examined by using Buongiorno’s model. The governing equations for the assumed flow problem are constituted under the boundary layer assumptions. After converting these equations in dimensionless form, the famous shooting technique is executed. A detailed physical significance is searched out in the presence of slip features. The variation of physical quantities, namely velocity, nanoparticles temperature, nano particles concentration, motile microorganism density, skin friction coefficient, local Nusselt number and motile organism density number are observed with detailed physical aspects for various flow controlling parameters.
Highlights
In recent years, nanofluids have proven to be a more convent heat transfer media in contrast to the heat transfer liquids
We aim to explore the bioconvection phenomenon in the steady flow of Eyring Powell nanofluid in presence of thermal radiation, activation energy and Wu’s slip slip features
0.5518 energy features in analysis are summarized as: current summarized as: slip effects, 0.5438 bioconvection ofare
Summary
Nanofluids have proven to be a more convent heat transfer media in contrast to the heat transfer liquids. Due to improved thermo-physical features, the nanoparticles are considered as a more constructive resource energy conversion and heat exchanger, which is quite necessitated in mechanical and engineering processes. The interaction of nanoparticles in base liquids can effectively enhance the cost-coefficient systems, which are related to the diverse mechanical and manufacturing processes. The foremost focus on thermo-physical properties of nanoparticles was put forward by Choi [1]. Many miscellaneous attempts regarding the interaction of nanoparticles was made by numerous researchers in the past few years. Madhu and Kishan [2]
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