The heat transportation features of current liquids are improved via suspension of nano-sized solid elements having diameter (< 100 nm), regarded as potential working liquids to utilize in automobile radiators, electronic chilling systems, solar collectors, heat pipes and nuclear reactors. The present investigation explores the simultaneous impacts of convective conditions, and stratifications in thermally radiated flow of magneto-Jeffrey nanomaterials, nonlinear convection, heat source and Joule heating are taken into account. Implementation of boundary layer theory leads to rheological model of considered problem. The relevant variables have been used to convert PDEs into ODEs. Convergent solutions are achieved through homotopic algorithm, while significance of sundry factors are provided via graphical and tabular data. We have examined reduction in liquid temperature along with concentration subject to higher thermal/concentration stratification factors.

通过悬浮直径为（<100 nm）的纳米级固体元素，改善了当前液体的传热特性，这些元素被认为是潜在的工作液体，可用于汽车散热器，电子制冷系统，太阳能收集器，热管和核反应堆。本研究探讨了对流条件的同时影响，并考虑了磁性-Jeffrey纳米材料的热辐射流中的分层，非线性对流，热源和焦耳热。边界层理论的实施导致了所考虑问题的流变模型。相关变量已用于将PDE转换为ODE。通过同位算法可以实现收敛解，而通过图形和表格数据可以提供各方面因素的重要性。