Correlation between Interfacial Structure, Tracer Diffusion and Crystal Growth in Nanocrystalline Metals and Alloys

TL;DR: A comprehensive overview of boundary diffusion theory with emphasis on the interpretation of concentration profiles measured in diffusion experiments is given in this paper, where the most important situations encountered in boundary diffusion experiments are considered, such as diffusion in the B and C regimes, diffusion in presence of segregation and diffusion in multiple grain boundaries.

TL;DR: In this paper, the authors discuss the preparation, the atomic structure and the properties of nanometer structured solids that consist either totally or partially of amorphous components, and suggest that it is the variation of the boundary conditions applied for preparing nano-structures that open the way to a variety of materials with new atomic arrangements/new properties ranging from nano-glasses to switchable atomic quantum transistors.

TL;DR: This new class of noncrystalline materials may open the way to technologies utilizing the new properties of nanoglasses, which were noted to be more ductile, more biocompatible, and catalytically more active than the corresponding melt-quenched glasses.

TL;DR: In this paper, an overview of diffusion in nanocrystalline metals and alloys is presented, with an emphasis on the interfacial characteristics that affect diffusion, such as structural relaxation, grain growth, porosity, and specific type of interface.