Hyperordered Structures in Materials

This book introduces characterizations of hyperordered structures using latest quantum beam technologies, the advanced theoretical methods for understanding the roles of the structures, and the state-of-the-arts materials containing the structures.

In this book, the authors focus on the importance of defect complexes to improve functionality of crystals and that of orders of network structures to improve functionality of glass materials. These features can be regarded as interphases between perfect crystals and perfect amorphous, and they are the key factor for the evolution of materials science to a new dimension. The authors call such interphases "hyperordered structures" in this book.

This is the first book that comprehensively summarizes glass science, defect science, and quantum beam science. It is valuable not only for active researchers in industry and academia but also graduate students.

Connects crystal science and amorphous science Deals with materials design by topology control Provides a concept of interphases that can evolve materials science

Auteur

Koichi Hayashi was born in Kagoshima, Japan, in 1968. He obtained his B.Sc. (1990) and M.Sc. (1992) degrees from Kyushu University, and D.Sc. (1996) degree from Kyoto University. He was a research associate in Kyoto University (1996-2000) and Tohoku University (2000-2003). Then, he promoted to an associate professor (2003-2015) in Tohoku University. He moved to Nagoya Institute of Technology as a full professor in 2015.

He has been engaged in developments of new X-ray analysis methods to date. Recently, he has investigated local structures around dopants in state-of-the-arts materials by means of XFH. In November 2020, he launched a huge national project (JSPS Grant-in-Aid for Transformative Research Areas (A)) of "Hyper-ordered Structures Science" as a representative.

Texte du rabat

This book introduces characterizations of hyperordered structures using latest quantum beam technologies, the advanced theoretical methods for understanding the roles of the structures, and the state-of-the-arts materials containing the structures. In this book, the authors focus on the importance of defect complexes to improve functionality of crystals and that of orders of network structures to improve functionality of glass materials. These features can be regarded as interphases between perfect crystals and perfect amorphous, and they are the key factor for the evolution of materials science to a new dimension. The authors call such interphases "hyperordered structures" in this book. This is the first book that comprehensively summarizes glass science, defect science, and quantum beam science. It is valuable not only for active researchers in industry and academia but also graduate students.

Contenu
From point defects to defect complexes.- Topological order and hyperorder in oxide glasses and liquids.- Atomic-resolution holography.- X-ray and neutron pair distribution function analysis.- Angstrom-beam electron diffraction technique for amorphous materials.- Dynamics.- Property measurements of molten oxides at high temperature using containerless methods.- Density functional theory calculations for materials with complex structures.- Molecular dynamics.- Reverse Monte Carlo modeling of noncrystalline and crystalline materials.- Structural-order analysis based on applied mathematics.- Machine learning.- Dielectric Materials with Hyperordered Structures.- Hyperordered Structures in Microporous Frameworks in Zeolites.- Glasses with hyperordered structures.- Biological materials.- Battery and fuel cell materials with hyperordered structures.- Superconductors with hyperordered structures.- Ordered and disordered metaloxide for biomass conversion.