Diffusion of stratification based chemically reactive Jeffrey liquid featuring mixed convection

This investigation elaborates simultaneous attributes of chemical reaction and dual stratification in magnetized Jeffrey liquid flow by the vertical cylinder movement. Consideration of mixed convection leads to coupled flow phenomena. Heat sink/source and thermal radiation effect are accounted to scrutinize the heat transport features. The mathematical system is simplified by implementing boundary-layer approach. The process of non-dimensionalization is done by introducing appropriate variables. Computational outcomes are achieved via homotopic criteria. Graphical illustrations are presented to visualize the solution expressions. Rate of heat-mass transfer is noticed higher when stratification variables are augmented however an increment in stratification variables yields lower solutal and thermal fields. It is worth to mention that results for flat surface can be recovered in the absence of curvature parameter.

Automated summary

This investigation explores the simultaneous attributes of chemical reaction and dual stratification in magnetized Jeffrey liquid flow, considering mixed convection leading to coupled flow phenomena. The mathematical system is simplified through the boundary-layer approach, and computational outcomes are achieved via homotopic criteria. It is found that an increase in stratification variables leads to higher rate of heat-mass transfer but lower solutal and thermal fields.