Applications of Nanofluid for Heat Transfer Enhancement

Chapter 1: Nanofluid: Definition and Applications

• Abstract
• 1.1. Introduction
• 1.2. Simulation of nanofluid flow and heat transfer

Chapter 2: Nanofluid Natural Convection Heat Transfer

• Abstract
• 2.1. CuO–water nanofluid hydrothermal analysis in a complex-shaped cavity
• 2.2. Natural convection heat transfer in a nanofluid filled inclined L-shaped enclosure
• 2.3. Natural convection heat transfer in a nanofluid filled enclosure with elliptic inner cylinder
• 2.4. Natural convection in a nanofluid filled concentric annulus between an outer square cylinder and an inner circular cylinder
• 2.5. Natural convection in a nanofluid filled concentric annulus with inner elliptic cylinder using LBM
• 2.6. Natural convection in a nanofluid filled square cavity with curve boundaries
• 2.7. Nanofluid heat transfer enhancement and entropy generation
• 2.8. Two phase simulation of nanofluid flow and heat transfer using heatline analysis

Chapter 3: Nanofluid Forced Convection Heat Transfer

• Abstract
• 3.1. Effect of nonuniform magnetic field on forced convection heat transfer of Fe₃O₄-water nanofluid
• 3.2. MHD nanofluid flow and heat transfer considering viscous dissipation
• 3.3. Forced convection heat transfer in a semiannulus under the influence of a variable magnetic field
• 3.4. MHD nanofluid flow and heat transfer considering viscous dissipation
• 3.5. Nanofluid flow and heat transfer between parallel plates considering Brownian motion using DTM
• 3.6. Effect of Lorentz forces on forced convection nanofluid flow over a stretched surface
• 3.7. Forced convective heat transfer of magnetic nanofluid in a double-sided, lid-driven cavity with a wavy wall

Chapter 4: Nanofluid Flow and Heat Transfer in the Presence of Thermal Radiation

• Abstract
• 4.1. MHD free convection of Al₂O₃–water nanofluid considering thermal radiation
• 4.2. Unsteady nanofluid flow and heat transfer in the presence of magnetic field considering thermal radiation
• 4.3. Effect of thermal radiation on magnetohydrodynamic nanofluid flow and heat transfer by means of two-phase model
• 4.4. Ferrofluid flow and heat transfer in a semiannulus enclosure in the presence of magnetic source considering thermal radiation
• 4.5. Nanofluid flow and heat transfer over a stretching porous cylinder considering thermal radiation

Chapter 5: Nanofluid Flow and Heat Transfer in the Presence of Electric Field

• Abstract
• 5.1. Electrohydrodynamic free convection heat transfer of a nanofluid in a semiannulus enclosure with a sinusoidal wall
• 5.2. Effect of electric field on hydrothermal behavior of nanofluid in a complex geometry
• 5.3. Electrohydrodynamic nanofluid flow and forced convective heat transfer in a channel
• 5.4. Electrohydrodynamic nanofluid hydrothermal treatment in an enclosure with sinusoidal upper wall
• 5.5. Electrohydrodynamic nanofluid force convective heat transfer considering electric field dependent viscosity

Chapter 6: Nanofluid Flow and Heat Transfer in the Presence of Constant Magnetic Field

• Abstract
• 6.1. Entropy generation of nanofluid in the presence of magnetic field using lattice Boltzmann method
• 6.2. MHD natural convection in a nanofluid-filled inclined enclosure with sinusoidal wall using CVFEM
• 6.3. Effects of MHD on Cu–water nanofluid flow and heat transfer by means of CVFEM
• 6.4. Heat flux boundary condition for nanofluid-filled enclosure in the presence of magnetic field
• 6.5. Magnetic field effect on nanofluid flow and heat transfer using KKL model
• 6.6. Magnetohydrodynamic free convection of Al₂O₃–water nanofluid considering thermophoresis and Brownian motion effects
• 6.7. Simulation of MHD CuO–water nanofluid flow and convective heat transfer considering Lorentz forces
• 6.8. Three-dimensional mesoscopic simulation of magnetic field effect on natural convection of nanofluid
• 6.9. Two-phase simulation of nanofluid flow and heat transfer in an annulus in the presence of an axial magnetic field
• 6.10. Magnetic field effect on unsteady nanofluid flow and heat transfer using Buongiorno model
• 6.11. Free convection of magnetic nanofluid considering MFD viscosity effect

Chapter 7: Nanofluid Flow and Heat Transfer in the Presence of Variable Magnetic Field

• Abstract
• 7.1. Effect of space dependent magnetic field on free convection of Fe₃O₄–water nanofluid
• 7.2. Simulation of ferrofluid flow for magnetic drug targeting using lattice Boltzmann method
• 7.3. Magnetic nanofluid forced convective heat transfer in the existence of variable magnetic field using two-phase model
• 7.4. Nonuniform magnetic field effect on nanofluid hydrothermal treatment considering Brownian motion and thermophoresis effects
• 7.5. Ferrofluid-mixed convection heat transfer in the existence of variable magnetic field
• 7.6. Influence of magnetic field on heat transfer of magnetic nanofluid in a sinusoidal double pipe heat exchanger

Chapter 8: Nanofluid Conductive Heat Transfer in Solidification Mechanism

• Abstract
• 8.1. Discharging process expedition of NEPCM in Y-shaped fin-assisted latent heat thermal energy storage system
• 8.2. Snowflake-shaped fin for expediting discharging process in latent heat thermal energy storage system containing nanoenhanced phase change material

Chapter 9: Nanofluid Flow and Heat Transfer in Porous Media

• Abstract
• 9.1. Nanofluid heat Transfer over a permeable stretching wall in a porous medium
• 9.2. Magnetohydrodynamic flow in a permeable channel filled with nanofluid
• 9.3. Heated permeable stretching surface in a porous medium using Nanofluid
• 9.4. Two phase modeling of nanofluid in a rotating system with permeable sheet
• 9.5. KKL correlation for simulation of nanofluid flow and heat transfer in a permeable channel

Appendix: Sample Codes for New Semianalytical and Numerical Methods