MicroComputed Tomography has become the gold standard for studying 3D microscopic structures nondestructively, and this book provides up-to-date coverage of the modality. The first part of the book focuses on methodology, covering experimental methods, data analysis, and visualization approaches. Emphasis is on fundamentals so that those new to the field can design their own effective microCT studies. The second part addresses various microCT applications, organized by type of microstructure so that the reader can appreciate approaches from other disciplines. The applications include porous solids, microstructural evolution, soft tissue studies, applications using x-ray phase contrast or x-ray scattering contrast, and multimode studies.

Each year synchrotron facilities, both in the United States and in other countries, are utilized for more applications of synchrotron radiation as they pertain to materials science. Both basic and applied research possibilities are manyfold, including studies of materials mentioned below and those that are yet to be discovered. The combination of synchrotron-based spectroscopic techniques with ever-increasing high-resolution microscopy allows researchers to study very small domains of materials in an attempt to understand their chemical and electronic properties. This is especially important for composites and related materials involving material bonding interfaces. This book brings together the materials science community and the characterization techniques that use synchrotron radiation. Topics include surfaces, interfaces, electronic materials, metal oxides, metal sulfides, radiation detector materials, thin films, carbides, polymers, alloys, nanoparticles, and metal composites. Results reported in the volume address recent advances in X-ray absorption and scattering, imaging, tomography, microscopy, and diffraction methods.

MicroComputed Tomography has become the gold standard for studying 3D microscopic structures nondestructively, and this book provides up-to-date coverage of the modality. The first part of the book focuses on methodology, covering experimental methods, data analysis, and visualization approaches. Emphasis is on fundamentals so that those new to the field can design their own effective microCT studies. The second part addresses various microCT applications, organized by type of microstructure so that the reader can appreciate approaches from other disciplines. The applications include porous solids, microstructural evolution, soft tissue studies, applications using x-ray phase contrast or x-ray scattering contrast, and multimode studies.