Mathematical analysis of heat and mass transfer on unsteady stagnation point flow of Riga plate with binary chemical reaction and thermal radiation effects

To aid in the prevention of reaction explosions, chemical engineers and scientists must analyze the Arrhenius kinetics and activation energies of chemical reactions involving binary chemical mixtures. Nanofluids with an Arrhenius kinetic are crucial for a broad variety of uses in the industrial sector, involving the manufacture of chemicals, thermoelectric sciences, biomedical devices, polymer extrusion, and the enhancement of thermal systems via technology. The goal of this study is to determine how the presence of thermal radiation influences heat and mass transfer during free convective unsteady stagnation point flow across extending/shrinking vertical Riga plate in the presence of a binary chemical reaction where the activation energy of the reaction is known in advance. For the purpose of obtaining numerical solutions to the mathematical model of the present issue the Runge-Kutta (RK-IV) with shooting technique in Mathematica was used. Heat and mass transfer processes, as well as interrupted flow phenomena, are characterized and explained by diagrams in the suggested suction variables along boundary surface in the stagnation point flow approaching a permeable stretching/shrinking Riga Plate. Graphs illustrated the effects of many other factors on temperature, velocity, concentration, Sherwood and Nusselt number as well as skin friction in detail. Velocity profile increased with Z,A and S and decreased with e. Increasing values of e, A and S decline the temperature profile. The concentration profile boosts up with Z, a and slow down with e, Sc,fl,6 and n1 parameters. Skin friction profile increased with Z and S and decreased with e. Nusselt number profile increased with S, Z, e and radiation. Sherwood number profile shows upsurges with e, Z, a, Sc,fl, S and n1 whereas slow down with 6. So that the verdicts could be confirmed, a study was done to compare the most recent research with the results that had already been published for a certain case. The outcomes demonstrated strong concordance between the two sets of results.

Automated summary

In order to prevent reaction explosions, chemical engineers and scientists analyze the kinetics and activation energies of chemical reactions involving binary chemical mixtures. Nanofluids with Arrhenius kinetics are important for various industrial uses. This study focuses on how thermal radiation affects heat and mass transfer during convective flow across a vertical plate with a binary chemical reaction. The mathematical model was solved using the Runge-Kutta method, and the results showed the effects of various factors on temperature, velocity, concentration, and skin friction. Comparisons with previous research confirmed the accuracy of the findings.