Condensed matter physics, Magnetization, Mössbauer spectroscopy, Magnetic anisotropy and Analytical chemistry are his primary areas of study. Teruya Shinjo is studying Ferromagnetism, which is a component of Condensed matter physics. His Magnetization research is multidisciplinary, relying on both Thin film and Deposition.
His Mössbauer spectroscopy research includes themes of Magnetism, Neutron diffraction, Hyperfine structure, Magnetic moment and SQUID. His Magnetic anisotropy research is multidisciplinary, incorporating perspectives in Ferromagnetic resonance and Quantum tunnelling. His Analytical chemistry research includes elements of Texture, Diffraction, Optics, Superstructure and Metal.
Teruya Shinjo mainly focuses on Condensed matter physics, Mössbauer spectroscopy, Magnetization, Analytical chemistry and Hyperfine structure. The various areas that Teruya Shinjo examines in his Condensed matter physics study include Giant magnetoresistance, Magnetoresistance and Spin polarization. His Mössbauer spectroscopy study integrates concerns from other disciplines, such as Magnetism and Metal.
His Analytical chemistry research incorporates elements of Deposition, Nuclear magnetic resonance and Epitaxy. His Hyperfine structure research focuses on Magnetic moment and how it relates to Magnetic structure. While the research belongs to areas of Superlattice, Teruya Shinjo spends his time largely on the problem of Thin film, intersecting his research to questions surrounding Superstructure.
Teruya Shinjo spends much of his time researching Condensed matter physics, Ferromagnetic resonance, Spin Hall effect, Spintronics and Spin pumping. He combines subjects such as Spin polarization and Magnetization with his study of Condensed matter physics. In his work, Domain wall, Nucleation, Perpendicular and Magnetization reversal is strongly intertwined with Hall effect, which is a subfield of Spin Hall effect.
His work in Spintronics addresses subjects such as Inverse, which are connected to disciplines such as Insulator. His Spin pumping research incorporates themes from Layer, Yttrium iron garnet, Spin wave and Graphene. His research in Ferromagnetism intersects with topics in Weyl semimetal and Magnetoresistance.
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LARGE MAGNETORESISTANCE OF FIELD-INDUCED GIANT FERRIMAGNETIC MULTILAYERS
Teruya Shinjo;Hidefumi Yamamoto.
Journal of the Physical Society of Japan (1990)
Voltage-induced perpendicular magnetic anisotropy change in magnetic tunnel junctions
T. Nozaki;Y. Shiota;M. Shiraishi;T. Shinjo.
Applied Physics Letters (2010)
MFM study of magnetic vortex cores in circular permalloy dots: behavior in external field
T. Okuno;K. Shigeto;T. Ono;K. Mibu.
Journal of Magnetism and Magnetic Materials (2002)
Erratum: Real-Space Observation of Current-Driven Domain Wall Motion in Submicron Magnetic Wires [Phys. Rev. Lett. 92 , 077205 (2004)]
A. Yamaguchi;T. Ono;S. Nasu;K. Miyake.
Physical Review Letters (2006)
Preparation and characterization of stoichiometric CaFeO3
Y. Takeda;S. Naka;M. Takano;T. Shinjo.
Materials Research Bulletin (1978)
Effect of Joule heating in current-driven domain wall motion
A. Yamaguchi;H. Tanigawa;T. Ono;S. Nasu.
arXiv: Materials Science (2004)
Preparation of ferrimagnetic magnetite microspheres for in situ hyperthermic treatment of cancer.
Masakazu Kawashita;Masashi Tanaka;Tadashi Kokubo;Yoshiaki Inoue.
Spin excitations of nanometric cylindrical dots in vortex and saturated magnetic states
L. Giovannini;F. Montoncello;F. Nizzoli;G. Gubbiotti.
Physical Review B (2004)
Mössbauer Effect in Antiferromagnetic Fine Particles
Journal of the Physical Society of Japan (1966)
Fe 57 Mössbauer Effect in Fe 2 B, FeB and Fe 3 C
Teruya Shinjo;Fumitake Itoh;Hideo Takaki;Yoji Nakamura.
Journal of the Physical Society of Japan (1964)
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