Elastic and Inelastic Scattering in Electron Diffraction and Imaging

Dr. Zhong Lin Wang is a preeminent physicist and materials scientist whose groundbreaking work has revolutionized the fields of nanotechnology, energy harvesting, and self-powered systems. He currently serves as the director of the Beijing Institute of Nanoenergy and Nanosystems and holds the distinguished titles of Regents' Professor and Hightower Chair (Emeritus) at the Georgia Institute of Technology. Dr. Wang is widely recognized as the pioneer of the nanogenerators field, which has enabled advancements in distributed energy, self-powered sensors, and large-scale blue energy. Additionally, he coined and developed the fields of piezotronics and piezo-phototronics, which have significant implications for third-generation semiconductors. Wang has also made outstanding contribution to fundamentals of electron microscopy. Dr. Wang s scientific impact is unparalleled.

I Diffraction and Imaging of Elastically Scattered Electrons.- 1. Basic Kinematic Electron Diffraction.- 2. Dynamic Elastic Electron Scattering I: Bloch Wave Theory.- 3. Dynamic Elastic Electron Scattering II: Multislice Theory.- 4. Dynamic Elastic Electron Scattering III: Other Approaches.- 5. Diffraction and Imaging of Reflected High-Energy Electrons from Bulk Crystal Surfaces.- II Diffraction and Imaging of Inelastically Scattered Electrons.- 6. Inelastic Excitations and Absorption Effect in Electron Diffraction.- 7. Semiclassical Theory of Thermal Diffuse Scattering.- 8. Dynamic Inelastic Electron Scattering I: Bloch Wave Theory.- 9. Reciprocity in Electron Diffraction and Imaging.- 10. Dynamic Inelastic Electron Scattering II: Green's Function Theory.- 11. Dynamic Inelastic Electron Scattering III: Multislice Theory.- 12. Dynamic Inelastic Electron Scattering IV: Modified Multislice Theory.- 13. Inelastic Scattering in Sub-Angstrom Electron Imaging and Holography    - 14. Dynamic theory of thermal diffusely scattered electrons.- 15. Electron diffuse scattering from crystals with correlated point defects. 16. Multiple inelastic electron scattering from thick crystals- 17. Inelastic Excitation of Crystals in Thermal Equilibrium with the Environment.- Appendixes.- A. Physical Constants, Electron Wavelengths, and Wave Numbers.- B. Properties of Fourier Transforms.- B.1. Identities.- C. Some Properties of Dirac Delta Functions.- C.1. Defining Relationships and Normalization Conditions.- C.2. Useful Representations of the Delta Function.- D. Integral Form of the Schrödinger Equation.- E. Some Useful Mathematical Relations.- References.