Satoshi Hirosawa performs multidisciplinary study in Condensed matter physics and Ferromagnetism in his work. He combines Ferromagnetism and Curie temperature in his studies. In his works, he performs multidisciplinary study on Curie temperature and Magnetic field. In his works, he performs multidisciplinary study on Magnetic field and Coercivity. His research on Coercivity frequently connects to adjacent areas such as Condensed matter physics. Satoshi Hirosawa integrates many fields, such as Quantum mechanics and Nuclear magnetic resonance, in his works. His research on Metallurgy frequently connects to adjacent areas such as Atom probe. His research on Atom probe frequently connects to adjacent areas such as Alloy. He undertakes interdisciplinary study in the fields of Alloy and Metallurgy through his research.
Satoshi Hirosawa applies his multidisciplinary studies on Quantum mechanics and Thermodynamics in his research. He merges Thermodynamics with Quantum mechanics in his study. Many of his studies involve connections with topics such as Coercivity and Condensed matter physics. His multidisciplinary approach integrates Coercivity and Magnet in his work. Satoshi Hirosawa merges Magnet with Magnetic field in his research. Satoshi Hirosawa integrates Magnetic field with Ferromagnetism in his research. By researching both Ferromagnetism and Condensed matter physics, Satoshi Hirosawa produces research that crosses academic boundaries. Satoshi Hirosawa connects Metallurgy with Chemical engineering in his research. He integrates many fields in his works, including Chemical engineering and Metallurgy.
His Magnetic anisotropy study is within the categories of Exchange bias and Magnetocrystalline anisotropy. Thermodynamics connects with themes related to Spring (device), Atmospheric temperature range, Diffusion, Thermal and Evaporation in his study. Diffusion and Quantum mechanics are frequently intertwined in his study. His Quantum mechanics study frequently draws parallels with other fields, such as Hall effect. Borrowing concepts from Magnetic field, he weaves in ideas under Hall effect. His Magnetic field study frequently draws connections to other fields, such as Magnetocrystalline anisotropy. His research is interdisciplinary, bridging the disciplines of Thermodynamics and Thermal. Mathematical analysis is intertwined with Extrapolation and Content (measure theory) in his research. In his articles, he combines various disciplines, including Extrapolation and Mathematical analysis.
His Transmission electron microscopy investigation overlaps with other disciplines such as Nanotechnology and Scanning electron microscope. By researching both Nanotechnology and Transmission electron microscopy, he produces research that crosses academic boundaries. His Scanning electron microscope study often links to related topics such as Composite material. His study on Composite material is mostly dedicated to connecting different topics, such as Shell (structure). Satoshi Hirosawa performs multidisciplinary study in Metallurgy and Alloy in his work. He conducts interdisciplinary study in the fields of Alloy and Metallurgy through his works. Condensed matter physics is frequently linked to Coercivity in his study. His Coercivity study frequently draws connections to adjacent fields such as Condensed matter physics. In his works, he conducts interdisciplinary research on Quantum mechanics and Nuclear magnetic resonance.
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Magnetization and magnetic anisotropy of R2Fe14B measured on single crystals
Satoshi Hirosawa;Yutaka Matsuura;Hitoshi Yamamoto;Setsuo Fujimura.
Journal of Applied Physics (1986)
Nd–Fe–B Permanent Magnet Materials
Masato Sagawa;Satoshi Hirosawa;Hitoshi Yamamoto;Setsuo Fujimura.
Japanese Journal of Applied Physics (1987)
Magnetic properties of rare-earth-iron-boron permanent magnet materials
M. Sagawa;S. Fujimura;H. Yamamoto;Y. Matsuura.
Journal of Applied Physics (1985)
Coercivity enhancement of hydrogenation–disproportionation–desorption–recombination processed Nd–Fe–B powders by the diffusion of Nd–Cu eutectic alloys
H. Sepehri-Amin;H. Sepehri-Amin;T. Ohkubo;T. Nishiuchi;S. Hirosawa.
Scripta Materialia (2010)
Magnetic properties of the Nd2(Fe1−xCox)14B system
Y. Matsuura;S. Hirosawa;H. Yamamoto;S. Fujimura.
Applied Physics Letters (1985)
High‐coercivity iron‐rich rare‐earth permanent magnet material based on (Fe, Co)3B‐Nd‐M (M=Al, Si, Cu, Ga, Ag, Au)
Satoshi Hirosawa;Hirokazu Kanekiyo;Minoru Uehara.
Journal of Applied Physics (1993)
Phase diagram of the Nd-Fe-B ternary system
Yutaka Matsuura;Satoshi Hirosawa;Hitoshi Yamamoto;Setsuo Fujimura.
Japanese Journal of Applied Physics (1985)
Dependence of coercivity on the anisotropy field in the Nd2Fe14B‐type sintered magnets
M. Sagawa;S. Hirosawa;K. Tokuhara;H. Yamamoto.
Journal of Applied Physics (1987)
Microstructure and magnetic properties of high-remanence Nd/sub 5/Fe/sub 71.5/Co/sub 5/B/sub 18.5/M (M=Al, Si, Ga, Ag, Au) rapidly solidified and crystallized alloys for resin-bonded magnets
H. Kanekiyo;M. Uehara;S. Hirosawa.
IEEE Transactions on Magnetics (1993)
Magnetotransport through the spin-reorientation transition in Tm2Fe14B
Jolanta Stankiewicz;Juan Bartolomé;Satoshi Hirosawa.
Journal of Physics: Condensed Matter (2001)
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