A diagnostic philosophy of rotational impacts on unsteady parabolic flow past of an impenetrable and electrically leading liquid past a consistently quickened boundless isothermal perpendicular plate within sight of a first-order chemical response with the absence of magnetohydrodynamic has been accounted for in the examination. All the while, the plate temperature is raised to T_∞ and concentration level close to the plate is occupied with time. The dimensionless differential condition is resolved with the help of the Laplace-change strategy. The temperature and velocity concentration profiles have been perused for various actual boundaries, first-order chemical response boundary, mass Grashof range, warm Grashof range, Schmidt number, Prandtl number, and time t. 2-D figures have been processed in MATLAB R2019. It is seen that the predominant velocity increases with extending assessment of warm Grashof or mass Grashof range. It is similarly observed that the velocity increases with lessening rotational limit. The pattern is essentially exchanged concerning the chemical reaction limit.

convective, heat and mass transfer, parabolic, chemical reaction, rotation, accelerated, vertical plate.

Received: April 12, 2021; Revised: May 3, 2021; Accepted: June 8, 2021; Published: September 24, 2021

How to cite this article: S. Dilip Jose and A. Selvaraj, Convective heat and mass transfer effects of rotation on parabolic flow past an accelerated isothermal vertical plate in the presence of chemical reaction of first order, JP Journal of Heat and Mass Transfer 24(1) (2021), 191-206. DOI: 10.17654/HM024010191

This Open Access Article is Licensed under Creative Commons Attribution 4.0 International License

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