Single-Phase Forced Convection in Microchannels -- Measurements of Single-Phase Pressure Drop and Heat Transfer Coefficient in Micro and Minichannels -- Steady State and Periodic Heat Transfer in Micro Conduits -- Flow Regimes in Microchannel Single-Phase Gaseous Fluid Flow -- Microscale Heat Transfer at Low Temperatures -- Convective Heat Transfer for Single-Phase Gases in Microchannel Slip Flow: Analytical Solutions -- Microscale Heat Transfer Utilizing Microscale and Nanoscale Phenomena -- Microfluidics in Lab-on-a-Chip: Models, Simulations and Experiments -- Transient Flow and Thermal Analysis in Microfluidics -- From Nano to Micro to Macro Scales in Boiling -- Flow Boiling in Minichannels -- Heat Removal Using Narrow Channels, Sprays and Microjets -- Boiling Heat Transfer in Minichannels -- Condensation Flow Mechanisms, Pressure Drop and Heat Transfer in Microchannels -- Heat Transfer Characteristics of Silicon Film Irradiated by Pico to Femtosecond Lasers -- Microscale Evaporation Heat Transfer -- Ultra — Thin Film Evaporation (UTF) — Application to Emerging Technologies in Cooling of Microelectronics -- Binary-Fluid Heat and Mass Transfer in Microchannel Geometries for Miniaturized Thermally Activated Absorption Heat Pumps -- Heterogeneous Crystallization of Amorphous Silicon Accelerated by External Force Field: Molecular Dynamics Study -- Hierarchical Modeling of Thermal Transport from Nano-to-Macroscales -- Evaporative Heat Transfer on Horizontal Porous Tube -- Micro and Miniature Heat Pipes -- Role of Microscale Heat Transfer in Understanding Flow Boiling Heat Transfer and Its Enhancement -- Heat Transfer Issues in Cryogenic Catheters -- Sorption Heat Pipe — A New Device for Thermal Control and Active Cooling -- Thermal Management of Harsh-Environment Electronics -- Thermal Transport Phenomenon in Micro Film Heated by Laser Heat Source.

This volume provides a comprehensive state-of-the art assessment of the fundamentals of the Microscale heat transfer and transport phenomena and heat transfer and applications in Microsystems. The modern trend toward miniaturization of devices requires a better understanding of heat mass transfer phenomena in small dimensions. Devices having dimensions of order of microns are being developed for use of cooling of integrated circuits, and in biochemicals-biomedical applications and cryogenics. Microelectromechanical systems (MEMS) have an important impact in medicine, bioengineering, information technologies and other industries.