The current model analyses the impacts of Magneto-Marangoni phenomena and explains the relevance of local thermal non-equilibrium effect on the Darcy-Forchheimer flow of an Ellis hybrid nanofluid over a rotating disc through Soret-Dufour effects and Joule heating. In this paper, the properties of heat transfer with LTNECs are examined using a straightforward mathematical model. The LTNE classical is used to produce two different basic thermal gradients for the liquid and solid phases. This model assists engineers in the design and development of sophisticated cooling systems, such as those found in electrical devices by providing insights into the characteristics of heat transport. It facilitates the study of liquid behaviour in natural systems, including groundwater flow in permeable medium, and environmental researchers may find it helpful for waste cleanup. In solving the resulting non-dimensional equations, the Bvp4c method is analytically exhausted. The outcomes show that the thermal field ratio of heat transfer in the solid and fluid phases reduces as the rate of the interphase heat transfer parameter rises, however the thermal outline and rate of warmth transfer in the compact phase increase.
Abbas et al. (Thu,) studied this question.