Strain And Dislocation Gradients From Diffraction: Spatially-resolved Local Structure And Defects (e-bog) af -
Gene Ice, Ice (redaktør)

Strain And Dislocation Gradients From Diffraction: Spatially-resolved Local Structure And Defects e-bog

473,39 DKK (inkl. moms 591,74 DKK)
This book highlights emerging diffraction studies of strain and dislocation gradients with mesoscale resolution, which is currently a focus of research at laboratories around the world. While ensemble-average diffraction techniques are mature, grain and subgrain level measurements needed to understand real materials are just emerging. In order to understand the diffraction signature of differen...
E-bog 473,39 DKK
Forfattere Gene Ice, Ice (redaktør)
Udgivet 7 april 2014
Længde 480 sider
Genrer PDND
Sprog English
Format epub
Beskyttelse LCP
ISBN 9781908979643
This book highlights emerging diffraction studies of strain and dislocation gradients with mesoscale resolution, which is currently a focus of research at laboratories around the world. While ensemble-average diffraction techniques are mature, grain and subgrain level measurements needed to understand real materials are just emerging. In order to understand the diffraction signature of different defects, it is necessary to understand the distortions created by the defects and the corresponding changes in the reciprocal space of the non-ideal crystals.Starting with a review of defect classifications based on their displacement fields, this book then provides connections between different dislocation arrangements, including geometrically necessary and statistically stored dislocations, and other common defects and the corresponding changes in the reciprocal space and diffraction patterns. Subsequent chapters provide an overview of microdiffraction techniques developed during the last decade to extract information about strain and dislocation gradients. X-ray microdiffraction is a particularly exciting application compared with alternative probes of local crystalline structure, orientation and defect density, because it is inherently non-destructive and penetrating.