Diffraction and Imaging Techniques in Material Science reviews recent developments in diffraction and imaging techniques used in the study of materials. It discusses advances in high-voltage electron microscopy, low-energy electron diffraction (LEED), X-ray and neutron diffraction, X-ray topography, mirror electron microscopy, and field emission microscopy. Organized into five parts encompassing nine chapters, this volume begins with an overview of the dynamical theory of the diffraction of high-energy electrons in crystals and methodically introduces the reader to dynamical diffraction in perfect and imperfect crystals, inelastic scattering of electrons in crystals, and X-ray production. It then explores back scattering effects, the technical features of high-voltage electron microscopes, and surface characterization by LEED. Other chapters focus on the kinematical theory of X-ray diffraction, techniques and interpretation in X-ray topography, and interpretation of the contrast of the images of defects on X-ray topographs. The book also describes theory and applications of mirror electron microscopy, surface studies by field emission of electrons, field ionization and field evaporation, and gas-surface interactions before concluding with a discussion on lattice imperfections. Scientists and students taking courses on diffraction and solid-state electron microscopy will benefit from this book.

Diffraction and Imaging Techniques in Material Science describes the various methods used to study the atomic structure of matter at an atomic scale based on the interaction between matter and radiation. It classifies the possible methods of observation by making a list of radiations on the basis of wavelength, including ions, X-ray photons, neutrons, and electrons. It also discusses transmission electron microscopy, the weak-beam method of electron microscopy, and some applications of transmission electron microscopy to phase transitions. Organized into 13 chapters, this volume begins with an overview of the kinematic theory of electron diffraction and the ways to treat diffraction by a deformed crystal. It discusses the dynamical theory of diffraction of fast electrons, the treatment of absorption in the dynamical theory of electron diffraction, the use of electron microscopy to study planar interfaces, and analysis of weak-beam images. The book also covers the use of computed electron micrographs in defect identification, crystallographic analysis of dislocation loops containing shear components, and detection and identification of small coherent particles. In addition, the reader is introduced to interpretation of diffuse scattering and short-range order, along with the crystallography of martensitic transformations. The remaining chapters focus on the working principle of the transmission electron microscope, experimental structure imaging of crystals, and the study of diffuse scattering effects originating from substitutional disorder and displacement disorder. The information on diffraction and imaging techniques in material science contained in this book will be helpful to students, researchers, and scientists.

This book explains concepts of transmission electron microscopy (TEM) and x-ray diffractometry (XRD) that are important for the characterization of materials. The fourth edition adds important new techniques of TEM such as electron tomography, nanobeam diffraction, and geometric phase analysis. A new chapter on neutron scattering completes the trio of x-ray, electron and neutron diffraction. All chapters were updated and revised for clarity. The book explains the fundamentals of how waves and wavefunctions interact with atoms in solids, and the similarities and differences of using x-rays, electrons, or neutrons for diffraction measurements. Diffraction effects of crystalline order, defects, and disorder in materials are explained in detail. Both practical and theoretical issues are covered. The book can be used in an introductory-level or advanced-level course, since sections are identified by difficulty. Each chapter includes a set of problems to illustrate principles, and the extensive Appendix includes laboratory exercises.

Treatise on Materials Science and Technology, Volume 4 covers the fundamental properties and characterization of materials, ranging from simple solids to complex heterophase systems. The book covers articles on advanced techniques by which thin films may be characterized; on diffusion in substitutional alloys; and on solid solution strengthening in face-centered cubic alloys. The text also includes articles on the thermodynamics of binary ordered intermetallic phases; and the major aspects of metal powder processing. Professional scientists and engineers, as well as graduate students in materials science and associated fields will find the book invaluable.

Materials Characterization Using Nondestructive Evaluation (NDE) Methods discusses NDT methods and how they are highly desirable for both long-term monitoring and short-term assessment of materials, providing crucial early warning that the fatigue life of a material has elapsed, thus helping to prevent service failures. Materials Characterization Using Nondestructive Evaluation (NDE) Methods gives an overview of established and new NDT techniques for the characterization of materials, with a focus on materials used in the automotive, aerospace, power plants, and infrastructure construction industries. Each chapter focuses on a different NDT technique and indicates the potential of the method by selected examples of applications. Methods covered include scanning and transmission electron microscopy, X-ray microtomography and diffraction, ultrasonic, electromagnetic, microwave, and hybrid techniques. The authors review both the determination of microstructure properties, including phase content and grain size, and the determination of mechanical properties, such as hardness, toughness, yield strength, texture, and residual stress. - Gives an overview of established and new NDT techniques, including scanning and transmission electron microscopy, X-ray microtomography and diffraction, ultrasonic, electromagnetic, microwave, and hybrid techniques - Reviews the determination of microstructural and mechanical properties - Focuses on materials used in the automotive, aerospace, power plants, and infrastructure construction industries - Serves as a highly desirable resource for both long-term monitoring and short-term assessment of materials

Physics of New Materials starts from basic science, specially solid-state physics, and then moves into the research and development of advanced materials. The emphasis of the discussions is concentrated on the electronicand atomic structures and properties of transition-metal systems, liquidand amorphous materials, the nano-phase materials, layered compounds, martensite and other structural-transformed materials, and ordered alloys. Though these discussions, the physical aspects and principles ofnew materials, such as strong ferromagnetic alloys, shape memory alloys, amorphous alloys, ultra-fine particles, intercalated layered compounds, deformable ceramics, and nuclear-physics techniques. In addition to these theoretical treatments, modern experimental techniques, exemplified by M|ssbauer spectroscopy and electron microscopy, demonstrate the vast scope of schemes needed in the development of new materials.

The aim of this book is to outline the physics of image formation, electron specimen interactions and image interpretation in transmission electron mic roscopy. The book evolved from lectures delivered at the University of Munster and is a revised version of the first part of my earlier book Elek tronenmikroskopische Untersuchungs- und Priiparationsmethoden, omitting the part which describes specimen-preparation methods. In the introductory chapter, the different types of electron microscope are compared, the various electron-specimen interactions and their applications are summarized and the most important aspects of high-resolution, analytical and high-voltage electron microscopy are discussed. The optics of electron lenses is discussed in Chapter 2 in order to bring out electron-lens properties that are important for an understanding of the function of an electron microscope. In Chapter 3, the wave optics of elec trons and the phase shifts by electrostatic and magnetic fields are introduced; Fresnel electron diffraction is treated using Huygens' principle. The recogni tion that the Fraunhofer-diffraction pattern is the Fourier transform of the wave amplitude behind a specimen is important because the influence of the imaging process on the contrast transfer of spatial frequencies can be described by introducing phase shifts and envelopes in the Fourier plane. In Chapter 4, the elements of an electron-optical column are described: the electron gun, the condenser and the imaging system. A thorough understanding of electron-specimen interactions is essential to explain image contrast.