MHD bioconvectional flow of Jeffrey nanofluid with motile microorganisms over a stretching sheet: solar radiation applications

Abstract

Nanofluids play a role in thermal energy tools, helping to improve the performance of thermal and mass transport equipment while also lowering the device's mass and generating electricity. Scholars conducted observational and methodological study studies on flat plate with solar thermal radiation, using nanofluids with specified components (nanofluids) as conventional fluids, to improve the effectiveness of flat plate solar collectors. The current study examines the bioconvection slip flow of Jeffrey nanofluid against a stretching sheet using activation energy, solar radiation and viscous dissipation. The heat and mass transmission are discussed using the Buongiorno nanofluid model. The non-dimensional form of the formulated flow equations is obtained. An appropriate similarity transform method is used to convert the system of PDEs into ODEs. The structure of ordinary differential equations (ODEs) is handled by employing the MATLAB bvp4c tool. A comprehensive graphical analysis is done for the created flow model and impacted parameters. The velocity profile is observed to decay due to the slip phenomena. Bioconvection Rayleigh number and the buoyancy ratio parameter demonstrate the downward trend over the flow panel. The heat panel exhibits the enhancement over the temperature ratio parameter and temperature-dependent Biot number.