Heat and fluid flow in microscale and nanoscale structures

Over the last 20 years, micro/nanoscale flow and heat transfer have been a most active area of interdisciplinary research, involving scientists from various specialities including engineering, physics, chemistry and materials science. Presenting state-of-the-art knowledge in heat transfer and fluid flow in micro- and nanoscale structures, this book provides invaluable information for both graduate researchers and R&D engineers in industry and consultancy. All of the chapters are invited contributions from some of the most prominent scientists in the field and follow a unified outline and presentation to aid accessibility.

• Chapter 1 Miniature and microscale energy systems: Introduction
• Overview
• Scaling
• Thermally based power systems
• Future directions. Chapter 2 Nanostructures for thermoelectric energy: Introduction
• Thermoelectric effects and devices with bulk materials
• Nanostructures for solid-state energy conversion
• Summary. Chapter 3 Heat transport in superlattices and nanowires: Introduction
• Superlattices
• Nanowires and nanotubes
• Heat transport in bulk materials by phonons
• Heat transport in low-dimensional structures
• Survey of previous work
• Summary. Chapter 4 Thermomechanical formation and thermal detection of polymer nanostructures: Introduction
• Relaxation kinetics in nanostructured polymer films
• Modeling and simulation of nanometer-scale thermomechanical data bit formation
• Thermal data reading and topography mapping
• Summary and conclusions. Chapter 5 Two-phase flow microstructures in thin geometries: multi-field modelling: Introduction
• Global characteristics
• Local flow characteristics
• Summary. Chapter 6 Radiative energy transport at the spatial and temporal icro/nanoscales: Introduction
• Fundamentals
• Applications
• Future directions and concluding remarks. Chapter 7 Direct simulation Monte Carlo of gaseous flow and heat transfer in a microchannel: Introduction
• Description of the DSMC method
• DSMC simulation of microchannel
• Results and discussion
• Conclusions. Chapter 8 DSMC modeling of near-interface transport in liquid-vapor phase-change processes with multiple microscale effects: Introduction
• Phase equilibrium in microscale multiphase systems
• Molecular transport at interfaces
• High Knudsen number and nonequilibrium effects
• Variation of interfacial tension with interface curvature
• Liquid phase and interfacial region effects
• DSMC modeling of combined effects during vaporization and condensation
• Concluding remarks. Chapter 9 Molecular dynamics simulation of nanoscale heat and fluid flow: Introduction
• Basic equations and finite difference scheme
• Intermolecular potential model
• Macroscopic properties
• Boundary conditions and simulation system
• MD application to heat and fluid flow
• Future development.