Numerical simulations for thermally developed double diffusion flow of nanoparticles due to elongated cylinder with multiple slip effects: Applications to energy storage system

Based on peak thermal performances of nanofluid, different mathematical models are developed. In current analysis, the investigation for heat and mass transfer phenomenon associated to the magnetized nanofluid is examined. The analysis for heat transfer is addressed with applications of radiative phenomenon. The multiple slip effects are entertained for governing problem. The cause of induced flow is stretched cylinder. Mathematical model is solved shooting scheme. The validation for predicted results is presented to justify the solution. The analysis is observed for specific range of parameters like 0 <= M <= 1.5,0 <=gamma <= 0.6,0 <= S <= 0.3,0 <= R <= 0.5,0 <= Nt <= 0.4,0.5 <= A <= 2, and 0.2 <= B <= 0.8. The significance of thermally entertained nanofluid problem is physically inspected. It is evaluated that heat and mass transfer enhances due to curvature parameter. Low concentration field is examined for solutal stratification parameter. The obtained results present applications in enhancing thermal efficiency of solar systems, energy applications, heat transfer devices, chemical processes, cooling phenomenon, etc.