Yutaka Shimada spends much of his time researching Condensed matter physics, Magnetic anisotropy, Ferromagnetism, Thin film and Coercivity. His studies deal with areas such as Vortex, Magnetization, Epitaxy and Anisotropy as well as Condensed matter physics. His Magnetic anisotropy research is multidisciplinary, incorporating perspectives in Domain wall and Nuclear magnetic resonance.
His research in Nuclear magnetic resonance intersects with topics in Sputtering, Annealing, Optoelectronics, Analytical chemistry and Alloy. His Ferromagnetism study combines topics in areas such as Electrical resistivity and conductivity and Nucleation. His study in Coercivity is interdisciplinary in nature, drawing from both Crystallography, Crystallographic defect, Magnetic nanoparticles and Particle size.
His scientific interests lie mostly in Condensed matter physics, Magnetic anisotropy, Thin film, Nuclear magnetic resonance and Magnetization. In his work, Magnetic susceptibility is strongly intertwined with Anisotropy, which is a subfield of Condensed matter physics. His Magnetic anisotropy research is multidisciplinary, incorporating elements of Single crystal, Magnetic nanoparticles and Demagnetizing field.
His work deals with themes such as Optoelectronics, Composite material, Optics and Analytical chemistry, which intersect with Thin film. In his research on the topic of Nuclear magnetic resonance, Magnetostriction is strongly related with Amorphous solid. He combines subjects such as Crystallography and Annealing with his study of Sputtering.
His primary areas of investigation include Condensed matter physics, Thin film, Nuclear magnetic resonance, Magnetic anisotropy and Composite material. His Condensed matter physics research incorporates themes from Ferromagnetic resonance, Magnetization and Magnetization dynamics. His Magnetization research incorporates elements of Epitaxy and Ferrite.
His studies in Thin film integrate themes in fields like Optoelectronics and Coercivity, Analytical chemistry. The concepts of his Nuclear magnetic resonance study are interwoven with issues in Amorphous solid, Radio frequency and Sputter deposition, Sputtering. Yutaka Shimada has included themes like Remanence and Anisotropy in his Magnetic anisotropy study.
The scientist’s investigation covers issues in Condensed matter physics, Thin film, Nuclear magnetic resonance, Anisotropy and Ferromagnetism. The various areas that Yutaka Shimada examines in his Condensed matter physics study include Magnetic anisotropy, Ferromagnetic resonance, Epitaxy and Noise. His work carried out in the field of Thin film brings together such families of science as Optoelectronics and Magnetization.
His research integrates issues of Particle size, Sputter deposition, Eddy current and Analytical chemistry in his study of Nuclear magnetic resonance. As part of his studies on Anisotropy, Yutaka Shimada often connects relevant areas like Coercivity. His biological study spans a wide range of topics, including Nanostructured materials, Iron alloys, Metallurgy, Crystallite and Magnetostriction.
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Size effect on the crystal phase of cobalt fine particles
Osamu Kitakami;Hisateru Sato;Yutaka Shimada;Futami Sato.
Physical Review B (1997)
Chemical-order-dependent magnetic anisotropy and exchange stiffness constant of FePt (001) epitaxial films
S. Okamoto;N. Kikuchi;O. Kitakami;T. Miyazaki.
Physical Review B (2002)
Lowering of ordering temperature for fct Fe–Pt in Fe/Pt multilayers
Yasushi Endo;Nobuaki Kikuchi;Osamu Kitakami;Yutaka Shimada.
Journal of Applied Physics (2001)
Microfabrication and characteristics of magnetic thin-film inductors in the ultrahigh frequency region
M. Yamaguchi;K. Suezawa;K. I. Arai;Y. Takahashi.
Journal of Applied Physics (1999)
Low-temperature ordering of L10?CoPt thin films promoted by Sn, Pb, Sb, and Bi additives
O. Kitakami;Y. Shimada;K. Oikawa;H. Daimon.
Applied Physics Letters (2001)
Effect of interdot magnetostatic interaction on magnetization reversal in circular dot arrays
V. Novosad;V. Novosad;K. Yu. Guslienko;H. Shima;Y. Otani.
Physical Review B (2002)
Size effect on the ordering of L10 FePt nanoparticles
T. Miyazaki;O. Kitakami;S. Okamoto;Y. Shimada.
Physical Review B (2005)
Structure and magnetism of hcp-Co fine particles
H. Sato;Osamu Kitakami;T. Sakurai;Y. Shimada.
Journal of Applied Physics (1997)
High-frequency noise suppression in downsized circuits using magnetic granular films
S. Yoshida;H. Ono;S. Ando;F. Tsuda.
IEEE Transactions on Magnetics (2001)
Sensitive detection of irreversible switching in a single FePt nanosized dot
Nobuaki Kikuchi;Satoshi Okamoto;Osamu Kitakami;Y. Shimada.
Applied Physics Letters (2003)
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