Multiphase thermal systems (involving more than one phase or one component) have numerous applications in aerospace, heat-exchanger, transport of contaminants in environmental systems, and energy transport and energy conversion systems. Advances in understanding the behaviour of multiphase thermal systems could lead to higher efficiency energy production systems, improved heat-exchanger design, and safer and enhanced treatment of hazardous waste. But such advances have been greatly hindered by the strong effect of gravitational acceleration on the flow. Depending on the flow orientation and the phase velocities, gravitational forces could significantly alter the flow regime, and hence the pressure-drop and heat-transfer coefficients associated with the flow. A reduced gravity environment (or "microgravity"), provides an excellent tool to study the flow without the masking effects of gravity. This book presents for the first time a comprehensive coverage of all aspects of two-phase flow behaviour in the virtual absence of gravity.

Dr. Kamiel Gabriel is the Associate Provost of Research & Graduate Programs at UOIT; one of Canada's newest technical universities. He holds a Masters and Doctorate degrees in engineering, an MBA in international studies and a diploma in Space Science from the International Space University. Dr. Gabriel established the Microgravity Research Group in 1988. Since then, the group logged over 35 hours of near-zero gravity experiments aboard parabolic flights, space shuttles and in drop towers. He is internationally renowned for his pioneering work on multi-phase flow in near zero-gravity conditions. Dr. Gabriel resides in Whitby, Ontario, Canada.

Multiphase thermal systems have numerous applications in aerospace, heat-exchange, transport of contaminants in environmental systems, and energy transport and conversion systems. A reduced - or microgravity - environment provides an excellent tool for accurate study of the flow without the masking effects of gravity. This book presents for the first time a comprehensive coverage of all aspects of two-phase flow behaviour in the virtual absence of gravity.