Non-Newtonian nanofluid natural convection in a U-shaped cavity under magnetic field

“…Li et al 38 used fractional-stepbased multiphase LBM to study the boundary properties in magnetic multiphase flows. Similar work was proposed by Ali et al 39 They simulated incompressible magnetic multiphase non-Newtonian nanofluid flows using a magnetic field coupling fractional-step-based multiphase LBM. Garmroodi et al 40 examined the natural convection of non-Newtonian ferrofluid with the impact of the nonuniform magnetic field inside a porous elliptic domain.…”

Investigation of MHD free convection of power‐law fluids in a sinusoidally heated enclosure using the MRT‐LBM

“…Li et al 38 used fractional-stepbased multiphase LBM to study the boundary properties in magnetic multiphase flows. Similar work was proposed by Ali et al 39 They simulated incompressible magnetic multiphase non-Newtonian nanofluid flows using a magnetic field coupling fractional-step-based multiphase LBM. Garmroodi et al 40 examined the natural convection of non-Newtonian ferrofluid with the impact of the nonuniform magnetic field inside a porous elliptic domain.…”

Investigation of MHD free convection of power‐law fluids in a sinusoidally heated enclosure using the MRT‐LBM

“…In the past few decades, considerable attention has been paid to buoyancy-driven convection fluid flow and heat transfer in enclosures owing to its importance in various scientific fields, thermal solar collectors, buildings, nuclear reactors, cooling systems for electrical equipment, heat exchangers, and other industrial and engineering applications. [1][2][3][4][5][6] Researchers have long worked to enhance or invent novel methods for enhancing the heat transfer rate in thermal systems, resulting in higher heating system efficiency, lower fuel consumption, and cost-saving. Porous media can improve convective heat transfer by offering vast surface areas and intensifying flow mixture.…”

Newtonian and non‐Newtonian nanofluids with entropy generation in conjugate natural convection of hybrid nanofluid‐porous enclosures: A review

“…The magnetic field poses a significant factor that affects the efficiency of heat transfer in various industrial and engineering domains. Much work has therefore been done to investigate the influence of the magnetic field on heat transfer efficiency in cavities of various shapes such as F-shaped (Yadollahi et al , 2017), T-shaped (Hussein et al , 2016; Selimefendigil and Öztop, 2020a), H-shaped (Li et al , 2019; Rahimi et al , 2018), C-shaped (Makulati et al , 2016; Haq et al , 2018; Mliki et al , 2017), W-shaped (Massoudi et al , 2020a), L-shaped (Zhang et al , 2020; Ahmed et al , 2020), U-shaped (Selimefendigil and Öztop, 2020b; Ali et al , 2020), containing saturated porous media nanofluids. The results obtained from these works have shown that convective flow inside cavities increases by increasing the aspect ratio of Darcy number and cavity and decreases with the impact of Lorentz forces induced by magnetic field application.…”

Numerical analysis of magneto-natural convection and thermal radiation of SWCNT nanofluid inside T-inverted shaped corrugated cavity containing porous medium