Rheology of Particulate Dispersions and Composites provides comprehensive coverage of fundamental principles and equations that govern the rheology for particulate dispersions and two-phase solid composites. The rheological properties of suspensions, emulsions, bubbly liquids (foams) and other dispersions appear alongside those of solid composite materials for the first time in this unique, single source. The first section introduces applications, definitions, and important concepts such as fluid/solid/interfacial mechanics, bulk stress in dispersed systems, and dipole strength of particles. Subsequent chapters systematically consider the rheology for a wide variety of dispersions, including systems of: Rigid spherical and nonspherical particles (porous, nonporous, neutral, electrically charged, and magnetic particles) Nonrigid particles (deformable solid particles, droplets, bubbles, capsules, and core-shell particles) The final sections address the elastic properties of particle- and fiber-reinforced solid composite materials. They also discuss dynamic viscoelastic behavior of particulate dispersions and composites. From process design to novel materials development, Rheology of Particulate Dispersions and Composites illustrates the need for understanding rheological behavior throughout numerous commercial and industrial applications. This book is a versatile resource for students and scientists from a broad range of disciplines involved in the application, research, and development of dispersed systems.

In the design, processing, and applications of composite materials, a thorough understanding of the physical properties is required. It is important to be able to predict the variations of these properties with the kind, shape, and concentration of filler materials. The currently available books on composite materials often emphasize mechanical properties and focus on classification, applications, and manufacturing. This limited coverage neglects areas that are important to new and emerging applications. For the first time in a single source, this volume provides a systematic, comprehensive, and up-to-date exploration of the electromagnetic (electrical, dielectric, and magnetic), mechanical, thermal, and mass-transport properties of composite materials. The author begins with a brief discussion of the relevance of these properties for designing new materials to meet specific practical requirements. The book is then organized into five parts examining: The electromagnetic properties of composite materials subjected to time-invariant electric and magnetic fields The dynamic electromagnetic properties of composite materials subjected to time-varying electric and magnetic fields The mechanical elastic and viscoelastic properties of composites Heat transfer in composites and thermal properties (thermal conductivity, thermal diffusivity, coefficient of thermal expansion, and thermal emissivity) Mass transfer in composite membranes and composite materials Throughout the book, the analogy between various properties is emphasized. Electromagnetic, Mechanical, and Transport Properties of Composite Materials provides both an introduction to the subject for newcomers and sufficient in-depth coverage for those involved in research. Scientists, engineers, and students from a broad range of fields will find this book a comprehensive source of information.

Rheology of Particulate Dispersions and Composites provides comprehensive coverage of fundamental principles and equations that govern the rheology for particulate dispersions and two-phase solid composites. The rheological properties of suspensions, emulsions, bubbly liquids (foams) and other dispersions appear alongside those of solid composite materials for the first time in this unique, single source.

The first section introduces applications, definitions, and important concepts such as fluid/solid/interfacial mechanics, bulk stress in dispersed systems, and dipole strength of particles. Subsequent chapters systematically consider the rheology for a wide variety of dispersions, including systems of: Rigid spherical and nonspherical particles (porous, nonporous, neutral, electrically charged, and magnetic particles) Nonrigid particles (deformable solid particles, droplets, bubbles, capsules, and core-shell particles)

The final sections address the elastic properties of particle- and fiber-reinforced solid composite materials. They also discuss dynamic viscoelastic behavior of particulate dispersions and composites.

From process design to novel materials development, Rheology of Particulate Dispersions and Composites illustrates the need for understanding rheological behavior throughout numerous commercial and industrial applications. This book is a versatile resource for students and scientists from a broad range of disciplines involved in the application, research, and development of dispersed systems.