Mathematical modeling of rotational magneto nanofluid flow over a horizontal sheet with free stream velocity, thermal radiation, heat source and chemical reaction
DOI:
https://doi.org/10.22399/ijcesen.5325Keywords:
Nanofluid, MHD, Free stream velocity, Brownian diffusivity, Thermophoresis diffusivity, Thermal radiationAbstract
The steady two-dimensional MHD rotational nanofluid flow with free stream velocity, thermophoresis and Brownian motion effects over a moving horizontal sheet in presence of thermal radiation, heat source and first order chemical reaction is examined. Fourth order Runge-Kutta technique of MATLAB is implement to develope the problem. The numerical results of velocity, temperature and concentration fields are presented graphically and interpreted for various flow parameters. It is determined that rising value of magnetic, heat source and thermophoresis parameters enhance the primary velocity profiles and reduce the secondary velocity profiles while an opposite behavior of the other parameters is seen. The temperature is increased for heat source, thermophoresis and Brownian motion parameters but the concentration highly increased only for thermophoresis parameter. Also, the temperature strongly varies by variations in Prandtl number.
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