Using artificial neural network to optimize the flow and natural heat transfer of a magnetic nanofluid in a square enclosure with a fin on its vertical wall: a lattice Boltzmann simulation

“…In a variety of heat transfer applications, nanofluids have numerous properties that make them potentially useful, such as machining, pharmaceutical procedures, fuel cells, vehicle cooling/thermal control, domestic refrigerators, hybridpowered engines, chillers, microelectronics, lowering boiler flue gas temperature, and heat exchangers [29]. Zubaidi et al [30][31] has a great contribution regarding heat transfer applications of nanofluids. Jou and Tzeng [32] quantitatively investigated the vital convection enhancement of a twodimensional nanofluid.…”

Comparative Evaluation of the Optimal Auxiliary Function Method and Numerical Method to Explore the Heat Transfer between Two Parallel Porous Plates of Steady Nanofluids with Brownian and Thermophoretic Influences

“…In a variety of heat transfer applications, nanofluids have numerous properties that make them potentially useful, such as machining, pharmaceutical procedures, fuel cells, vehicle cooling/thermal control, domestic refrigerators, hybridpowered engines, chillers, microelectronics, lowering boiler flue gas temperature, and heat exchangers [29]. Zubaidi et al [30][31] has a great contribution regarding heat transfer applications of nanofluids. Jou and Tzeng [32] quantitatively investigated the vital convection enhancement of a twodimensional nanofluid.…”

Comparative Evaluation of the Optimal Auxiliary Function Method and Numerical Method to Explore the Heat Transfer between Two Parallel Porous Plates of Steady Nanofluids with Brownian and Thermophoretic Influences

Modeling and simulation of nanofluid in low Reynolds numbers using two-phase Lattice Boltzmann method based on mixture model

Heat transfer and irreversibility evaluation of non-Newtonian nanofluid density-driven convection within a hexagonal-shaped domain influenced by an inclined magnetic field