Numerical attribution of bioconvection magnetised electrical flow of thermal radiation in a nanoliquid with thermal/solutal convective curve surface
DOI:
https://doi.org/10.56042/ijct.v33i3.17347Keywords:
Bioconvection flow, Chemical reaction, Curved surface, Magnetised flow, Nanofluid, Thermal radiationAbstract
The influence of chemical species on the magnetised bioconvection flow of viscous nanofluid upon a curved surface is scrutinized in this exploration. Additionally, Brownian motion, heat generation/absorption, thermal radiation, and thermophoretic are included. Thermal/solutal, two constraints have been taken to compute the heat and mass transport analysis. To boost the effectiveness of the system, a method describing the viscous nanoliquid behaviour of the stretching curved is revealed by the present research's supplement. The dynamics of constitutive equations are rendered to model the transformation equation via the similarity factor. BVP4C techniques are then considered to solve the model transformation equation. The augmented values of the magnetic field parameter decay the velocity gradient. As a result, it is important to note that when the thermal radiation and Brownian motion variables concurrently escalate, the temperature fields intensify noticeably. The concentration gradient increased with the intensification values of the solutal Biot number and Brownian movement. Additionally, the local density number, heat, and mass transfer rates are computed. A tabulated evaluation of the present findings with outcomes in the research in the limited situation is performed to demonstrate the precision of the chosen numeric approach.
