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Heat and mass transfer analysis of MHD boundary layer flow with motile microorganisms over porous surfaces under variable wall thermal conditions

Muhammad Ashfaq, Khalil Hajlaoui, Issa El Glili, Youness Foukhari, Muhammad Arif, Rehman Ali Shah, Nashmi H. Alrasheedi, Nidhal Ben Khedher

2025Thermal Science and Engineering Progress9 citationsDOIOpen Access PDF

Abstract

Nanotechnology plays an important role in improving several sectors due to its ability to improve heat and mass transfer processes, making it extremely important for modern engineering as well as scientific applications. The current study aims to investigate the boundary layer flow over a moving horizontal surface immersed in a nanofluid, while incorporating viscous dissipation, flexible heating wall effects, and the influence of gyrotactic microorganisms. To simplify the equations that govern the fluid dynamics, appropriate similarity transformations are employed to reduce them into the system of ODEs. The modified mathematical equations are solved numerically utilizing MATLAB’s built-in solvers bvp4c, which has been developed for boundary value problems. After validating the computational model, numerical simulations are performed to examine the axial velocity field, variation in temperature, nanoparticle concentration, and the density distribution of microorganisms, along with several other significant physical parameters. The effects of key variables including the temperature-dependent thermal conductivity index, porosity, magnetic field strength, Brownian motion coefficients, plate kinematics, and dimensionless numbers (Lewis, Peclet, Prandtl, and Eckert) are systematically evaluated and presented through graphical and tabular representations. The results indicate that elevating the temperature-dependent index improves the thermal gradient, consequently reducing the thermal boundary layer thickness. This research also holds potential applications in improving thermophysical properties such as viscosity, convective heat transfer efficiency, thermal conductivity, and diffusivity in base fluids like water and oil. As the field of nanofluid dynamics advances, future studies are expected to yield further innovations in this multidisciplinary domain.

Topics & Concepts

MechanicsHeat transferBoundary layerThermal conductivityMass transferMaterials scienceMagnetohydrodynamicsPorous mediumBoundary value problemThermalDimensionless quantityNanofluidBoundary layer thicknessFlow (mathematics)Heat generationThermophoresisPorosityMagnetic fieldFluid dynamicsBrownian motionField (mathematics)Classical mechanicsThermodynamicsFinite difference methodSimilarity solutionThermal diffusivityThermal engineeringBoundary (topology)Thermal conductionPhysicsNanofluid Flow and Heat TransferHeat Transfer MechanismsHeat Transfer and Optimization
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