Description
Microscale and Nanoscale Heat Transfer
Analysis, Design, and Application
Coordinators: Rebay Mourad, Kakaç Sadik, Cotta Renato M.
Language: EnglishSubjects for Microscale and Nanoscale Heat Transfer:
Keywords
Thermal Conductivity Enhancement; Nusselt Number; Heat exchangers; Nanofluid Flow; Computerized fluid dynamics and heat transfer; Convective Heat Transfer; Cooling for MEMS and microelectronic devices; Water Nanofluids; Conjugate heat transfer; Slip Flow Regime; Fluid flow in microchannels; Base Fluid; Thermal Conductivity; Temperature Jump; Effective Thermal Conductivity; Microchannel Heat Sinks; Knudsen Number; GITT; Kapitza Resistance; Heat Flux; Wall Heat Flux Boundary Condition; Nanofluid Volume Fraction; Local Nusselt Number; Contact Angle; ITR; Single Phase Model; Viscous Dissipation; Porous Media; Thermophysical Properties; Slip Flow
· 17.8x25.4 cm · Hardback
Description
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Microscale and Nanoscale Heat Transfer: Analysis, Design, and Applications features contributions from prominent researchers in the field of micro- and nanoscale heat transfer and associated technologies and offers a complete understanding of thermal transport in nano-materials and devices. Nanofluids can be used as working fluids in thermal systems; the thermal conductivity of heat transfer fluids can be increased by adding nanoparticles in fluids. This book provides details of experimental and theoretical investigations made on nanofluids for use in the biomechanical and aerospace industries. It examines the use of nanofluids in improving heat transfer rates, covers the numerical approaches for computational fluid dynamics (CFD) simulation of nanofluids, and reviews the experimental results of commonly used nanofluids dispersed in both spherical and nonspherical nanoparticles. It also focuses on current and developing applications of microscale and nanoscale convective heat transfer.
In addition, the book covers a wide range of analysis that includes:
- Solid?liquid interface phonon transfer at the molecular level
- The validity of the continuum hypothesis and Fourier law in nanochannels
- Conventional methods of using molecular dynamics (MD) for heat transport problems
- The molecular dynamics approach to calculate interfacial thermal resistance (ITR)
- A review of experimental results in the field of heat pipes and two-phase flows in thermosyphons
- Microscale convective heat transfer with gaseous flow in ducts
- The application of the lattice Boltzmann method for thermal microflows
- A numerical method for resolving the problem of subcooled convective boiling flows in microchannel heat sinks
- Two-phase boiling flow and condensation heat transfer in mini/micro channels, and more
Microscale and Nanoscale Heat Transfer: Analysis, Design, and Applications
Interface Resistance and Thermal Transport in Nano-Confined Liquids. Molecular Dynamics Simulations for Water-Metal Interfacial Thermal Resistance. Convective Heat Transfer Enhancement with Nanofluids: A State-of-the-Art Review. Heat Conduction in Nanofluids. Thermophysical Properties of Nanofluids. Stability of Nanofluids: Fundamentals, State-of-the-Art, and Potential Applications. Numerical Approaches for Convective Heat Transfer with Nanofluids. Heat Pipes and Nanotechnologies. Nanofluid Flow Simulation as the Flow through the Porous Media. Convective Heat Transfer with Gaseous Flow in Microducts. Numerical Simulation of Combined Microscale Effects on Convective Heat Transfer in Single-Phase Flows. Numerical and Experimental Studies of Liquid and Gas Flow and Heat Transfer in Microchannel and Nozzle. Analytical-Numerical Solutions for Conjugated Heat Transfer in Multistream Microsystems. Direct-Inverse Problem Analysis in the Thermal Characterization of Microsystems. Application of the Lattice Boltzmann Method (LBM) to Thermal Microflows. Heat and Fluid Flow of Gases in Porous Media with Micropores: Slip Flow Regime. Numerical Analysis of Subcooled Convective Boiling in Microchannels. Two-Phase Flow in Microchannels.