Hayashi K., Higashikawa K., Kiss T., Tomita M., Inoue M., Furukawa K., Kikuchi M., Kobayashi S.-I., SATO K.-I., Nakashima T., Imado K.
Tsuchiya K., Yoshida K., Takahata K., Kizu K., Murakami H., Obana T., Natsume K., Hamaguchi S., Koide Y.
Ключевые слова: LTS, NbTi, Tokamak, high field magnets, joint resistances, joints, feeder, coils poloidal field, coils toroidal, design parameters, termination, self-field effect, distribution, fatigue behavior
Higashikawa K., Kiss T., Izumi T., Yoshizumi M., Fukuzaki T., Inoue M, Yoshida T., Kamihigoshi M., Uetsuhara D., Nishiura Y.
Tamura H., Mito T., Yanagi N., Ito S., Sagara A., Hashizume H., Natsume K., Hamaguchi S., Noguchi H., Terazaki Y., Kawai K., Seino Y., Ohinata T., Tanno Y.
Ключевые слова: DEMO, fusion magnets, HTS, REBCO, stacked blocks, coated conductors, helical winding, transport currents, Hall sensor, self-field effect, critical caracteristics, critical current, measurement technique, current waveforms, magnetic field dependence, numerical analysis, experimental results, modeling, current distribution, magnetic field distribution, stacked blocks, high field magnets
Ключевые слова: HTS, coated conductors, twisting, stacked blocks, cables, critical caracteristics, self-field effect, critical current
Ключевые слова: HTS, Bi2212, thin films, fabrication, nanodoping, nanoscaled effects, substrate single crystal, PLD process, X-ray diffraction, microstructure, lattice parameter, critical temperature, resistivity, temperature dependence, composition, pinning, critical caracteristics, critical current density, self-field effect, fabrication, experimental results
Ключевые слова: modeling computational, twisting, self-field effect, current, penetration depth, ac losses
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