Water thermal enhancement in a porous medium via a suspension of hybrid nanoparticles: MHD mixed convective Falkner's-Skan flow case study

“…The CNTs volume fraction is 0.17 and distributed uniformly along the beams, under the same geometrical assumptions R1 = R2 = 10, R/h = 10, 1 In this section, we investigate the thermal-dependent vibration of the system. There are several studies in which the effect of temperature variation on the structural behavior has been investigated [79,80]. Thus far, the mechanical properties of SWCNTs (10,10) and PMMA have been represented at room temperature (300 • K).…”

Natural Frequency Response of FG-CNT Coupled Curved Beams in Thermal Conditions

“…The CNTs volume fraction is 0.17 and distributed uniformly along the beams, under the same geometrical assumptions R1 = R2 = 10, R/h = 10, 1 In this section, we investigate the thermal-dependent vibration of the system. There are several studies in which the effect of temperature variation on the structural behavior has been investigated [79,80]. Thus far, the mechanical properties of SWCNTs (10,10) and PMMA have been represented at room temperature (300 • K).…”

Natural Frequency Response of FG-CNT Coupled Curved Beams in Thermal Conditions

“…Elboughdiri et al [ 14 ] passive control strategy is suggested for simulating thermally increased Jeffery nanofluid flows close to an impermeable barrier that has been suctioned. Wang et al [ 15 ] investigate hybrid nanoparticle suspension in MHD mixed convective Falkner-Skan flow for water thermal increase in a porous medium. MHD nanofluid flow in a Darcy-Forchheimer medium is numerically treated by Rasool et al [ 16 ] while taking radiative heat and mass transport laws into account.…”

Electroosmotic MHD ternary hybrid Jeffery nanofluid flow through a ciliated vertical channel with gyrotactic microorganisms: Entropy generation optimization

“…Of late, active control of porous media flows by virtue of nonlinear coupling between competing driving forces is giving rise to interesting physical outcomes as well as potential applications. Recently, several research groups have reported numerical studies on porous media flows of nanofluids in the presence of thermal and magnetic actuating forces. − Another prominent possibility is using direct current electric fields to manipulate fluid flow through electrokinetic principles. , The advent of paper-and-pencil-based devices have enabled a successful integration of electrokinetics with microfluidic porous media studies, with a diverse gamut of applications ranging from analytical procedures, such as mixing, separation, and on-chip energy harvesting, to point-of-care diagnostics. − Electrokinetic actuation has also been shown to enable active control of viscous fingering phenomenon in porous media by modifying the effective hydraulic resistance experienced by the fluids. , …”

Electrokinetics of Erosive Seepage through Deformable Porous Media