deliberated the impact of amphiphilic surfaces on the rheological properties and boundary slip of non-Newtonian fluid. His work helped develop and optimize industrial heat exchangers for high-viscosity non-Newtonian fluids. addressed numerical investigation of stream, thermal transport, and the mixing of a highly viscous non-Newtonian fluid was conducted. Firstly, Powell and Trying introduced non-Newtonian fluid in 1944. To develop innovative non-Newtonian nanofluid features, mathematicians worldwide are exploring novel research models throughout all periods of every day and night. When external forces influence non-Newtonian fluids, their density might change, resulting in more fluids or solids. Non-Newtonian nanofluids are employed in various technological, vehicle, and typical housekeeping machinery applications. Non-Newtonian fluids do not follow Newton’s viscosity law, having continuous viscosity regardless of stress. Furthermore, it is reported that the inclusion of dust particles or nanoparticles both cause to decline the primary and secondary velocities of fluid, and also dust particles decrease the temperature. By improving the diameter of nanoparticles D m, the axial velocity improves while transverse velocity and temperature show the opposite behaviors. It is observed that the rising strength of the rotating and magnetic parameters cause to recede the x- and y-axis velocities in the two phase fluid, but the temperature function exhibits an opposite trend. The study is compared to previously published work and determined to be perfect. An efficient code for the Runge–Kutta technique with a shooting tool is constructed in MATLAB script to obtain numeric results. The governing equations for the two phases model are partial differential equations later transmuted into ordinary ones via similarity transforms. In addition, nanofluid Cu-water is used as the heat-carrying fluid. ![]() The dust nanoparticles with superior thermal characteristics offer a wide range of uses in chemical and mechanical engineering eras and modern technology. Nanouids are the most important source of effective heat source, having many applications in scientific and technological processes. ![]() This study aimed to analyze the momentum and thermal transport of a rotating dusty Maxwell nanofluid flow on a magnetohydrodynamic Darcy–Forchheimer porous medium with conducting dust particles.
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