His primary areas of study are Crystallography, Crystal structure, Neutron diffraction, Rietveld refinement and Powder diffraction. The various areas that Fujio Izumi examines in his Crystallography study include Inorganic chemistry, Metal, Ion, Rendering and Diffusion. His Crystal structure research is multidisciplinary, incorporating elements of Valence, Lanthanide and Ferroelectricity.
His work deals with themes such as Stoichiometry, Perovskite, Molecular physics and Bond length, which intersect with Neutron diffraction. He interconnects Neutron powder diffraction and Inorganic compound in the investigation of issues within Rietveld refinement. His Powder diffraction research is multidisciplinary, relying on both Algorithm, Lattice and Diffraction.
Fujio Izumi mostly deals with Crystallography, Crystal structure, Neutron diffraction, Rietveld refinement and Superconductivity. Fujio Izumi works mostly in the field of Crystallography, limiting it down to topics relating to Ion and, in certain cases, Atom, as a part of the same area of interest. As a member of one scientific family, Fujio Izumi mostly works in the field of Crystal structure, focusing on Inorganic compound and, on occasion, High-temperature superconductivity.
His Neutron diffraction research incorporates elements of Bond length, Doping, Stoichiometry, Analytical chemistry and Perovskite. His Rietveld refinement research includes themes of X-ray crystallography, Oxide, Lattice and Lattice constant. In his work, Nickel is strongly intertwined with Copper, which is a subfield of Superconductivity.
Fujio Izumi mainly focuses on Crystallography, Crystal structure, Powder diffraction, Neutron diffraction and Rietveld refinement. His study in Crystallography is interdisciplinary in nature, drawing from both Ion and Phase transition. Fujio Izumi has researched Crystal structure in several fields, including Ab initio, Stacking, Molecule, Synchrotron and Silicate.
His studies deal with areas such as Computational physics, Electron density and Phase as well as Powder diffraction. His work in the fields of Neutron diffraction, such as Neutron powder diffraction, overlaps with other areas such as Nuclear density. His research integrates issues of Ionic bonding, Chemical bond, Fluorapatite and Neutron in his study of Rietveld refinement.
His primary scientific interests are in Crystallography, Neutron diffraction, Crystal, Ab initio and X-ray crystallography. His Crystallography research incorporates themes from Ion, Rendering and Diffusion. His Rendering research is multidisciplinary, incorporating perspectives in Voronoi diagram and Computational physics.
Fujio Izumi integrates Neutron diffraction and Nuclear density in his studies. His biological study spans a wide range of topics, including Computational chemistry, Coordination network, Open framework and Kinetic control. His Bond length study also includes
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VESTA 3 for three-dimensional visualization of crystal, volumetric and morphology data
Koichi Momma;Fujio Izumi.
Journal of Applied Crystallography (2011)
VESTA: a three-dimensional visualization system for electronic and structural analysis
Koichi Momma;Fujio Izumi.
Journal of Applied Crystallography (2008)
Raman spectrum of anatase, TiO2
Toshiaki Ohsaka;Fujio Izumi;Yoshinori Fujiki.
Journal of Raman Spectroscopy (1978)
A Rietveld-Analysis Programm RIETAN-98 and its Applications to Zeolites
Fujio Izumi;T. Ikeda.
Materials Science Forum (2000)
Three-dimensional Visualization in Powder Diffraction
Fujio Izumi;Koichi Momma.
Solid State Phenomena (2007)
Superconductivity in two-dimensional CoO2 layers.
Kazunori Takada;Hiroya Sakurai;Eiji Takayama-Muromachi;Fujio Izumi.
The Rietveld Method
Nihon Kessho Gakkaishi (1992)
Comparative study of defect structures in lithium niobate with different compositions
N. Iyi;K. Kitamura;F. Izumi;J.K. Yamamoto.
Journal of Solid State Chemistry (1992)
Crystal structures and ferroelectric properties of SrBi2Ta2O9 and Sr0.8Bi2.2Ta2O9
Y. Shimakawa;Y. Kubo;Y. Nakagawa;T. Kamiyama.
Applied Physics Letters (1999)
Crystal structure and ferroelectric properties of A Bi 2 Ta 2 O 9 ( A = Ca , Sr, and Ba)
Y. Shimakawa;Y. Kubo;Y. Nakagawa;S. Goto.
Physical Review B (2000)
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