Microfluid mechanics : principles and modeling

Publisher's Note: Products purchased from Third Party sellers are not guaranteed by the publisher for quality, authenticity, or access to any online entitlements included with the product. The rapid progress in fabricating and utilizing microelectromechanical (MEMS) systems during the last decade is not matched by corresponding understanding of the unconventional fluid flow involved in the operation and manufacture of these small devices. Providing such understanding is crucial to designing, optimizing, fabricating and operating improved MEMS devices. Microfluid Mechanics: Principles and Modeling is a rigorous reference that begins with the fundamental principles governing microfluid mechanics and progresses to more complex mathematical models, which will allow research engineers to better measure and predict reactions of gaseous and liquids in microenvironments.

Chapter 1: IntroductionChapter 2: Basic Kinetic TheoryChapter 3: Microfluid PropertiesChapter 4: Moment Method: Navier-Stokes and Burnett EquationsChapter 5: Statistical Method: Direct Simulations Monte Carlo Method and Information Preservation MethodChapter 6: Parallel Computing of DSMCChapter 7: Fluid/Solid Interface MechanismsChapter 8: Development of Hybrid Continuum/Particle MethodChapter 9: Low-Speed MicroflowsChapter 10: High-Speed MicroflowsChapter 11: Perturbation in Microflows