Non-Newtonian trihybrid nanofluids have unique thermal and flow characteristics that make them ideal for a wide range of heat transfer applications. These include controlling thermal systems in renewable energy, cooling electronic devices, boosting industrial process cooling, and optimizing heat exchanger performance. The objective of this research is to analyze the naturally occurring energy transfer behavior of a trihybrid Jeffrey nanofluid as it flows around a radiating, magnetized cylinder. The Keller-box scheme is employed to approximate the solution for the mathematical model that governs the issue. Numerical findings are produced using MATLAB, and these results additionally exhibit a high level of agreement with other findings published. The graphical outcomes of this investigation show that the physical groups are affected in two ways by the enhancement of magnetic parameter values. The trihybrid Jeffrey nanofluid's velocity, skin friction, and heat transport rate are all reduced by it. The temperature of the trihybrid Jeffrey nanofluid, however, has increased. An increase in all measured physical groups occurs with the enhancement of radiation parameter values. The energy transfer rate, velocity, or frictional forces of the hybrid/trihybrid nanofluids are enhanced when the Deborah number increases while their temperatures are reduced. As the volume fraction value rises, the adoption of the trihybrid nonsolid (Cu-Fe3O4-SiO2) increases the Nusselt number by 0.01% to 4% and decreases drag force by 1.1% to 8% compared to a hybrid nanosolid (Fe3O4-SiO2).
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