Ключевые слова: MgB2/Cu, MgB2/Fe, coils, ac losses, heating rates, heat transfer, modeling, numerical analysis
Ключевые слова: MgB2/Cu, MgB2/Fe, wires monofilamentary, current transfer, sheath, barriers, current distribution, electric field distribution, modeling, numerical analysis, length
Tomsic M., Rindfleisch M., Doll D., Baig T., Martens M., Poole C., Deissler R.J., Amin A.A., Akkus O., Sabri L.
Ключевые слова: MgB2/Ti, MgB2/Cu/Nb, wires monofilamentary, sheath, heat treatment, fabrication, phase formation, microstructure, resistive transition
Ключевые слова: MgB2/Cu, MgB2/Cu-Ni, MgB2/Al, Rutherford cables, design parameters, PIT process, diffusion process, ac losses, eddy currents, interstrand contact resistances, critical current, current decay, magnetic field dependence, temperature dependence, resistive transition, frequency dependence, experimental results
Ключевые слова: MgB2/Cu/Nb, wires, fabrication, pressure effect, PIT process, densification, critical caracteristics, Jc/B curves, temperature dependence, n-value, porosity, microstructure
Ключевые слова: MgB2/Cu, wires monofilamentary, microstructure, diffusion process, Jc/B curves, fabrication, experimental results
Ключевые слова: MgB2/Cu-Ni, in-situ process, precursors, bulk, PIT process, wires multifilamentary, microstructure, fabrication, grain size, resistivity, critical caracteristics, Jc/B curves
Ключевые слова: MgB2/Cu, wires, in-situ process, doping effect, densification, heat treatment, annealing process, critical caracteristics, Jc/B curves, fabrication
Ключевые слова: MgB2, bulk, MgB2/Cu/Nb, wires, fabrication, composition, powder processing, lattice parameter, microstructure, critical temperature, critical current density, synchrotron
Ключевые слова: MgB2/Cu, wires monofilamentary, sheath, wires multifilamentary, critical caracteristics, fabrication, diffusion process, Jc/B curves, critical current, magnetic field dependence, anisotropy, aspect ratios, ac losses, temperature dependence, mechanical properties, strain effects, experimental results
Ключевые слова: quench protection, minimum quench energy, normal zone propagation, stability, coils insert, design parameters, MgB2/Cu/Ni
Rakov D.N., Belotelova Y.N., Krinitsina T.P., Kuznetsova E.I., Blinova Y.V., Sudareva S.V., Degtyarev M.V., Romanov E.P.
Ключевые слова: MgB2/Cu/Nb, tapes monofilamentary, stability, composites, ex-situ process, PIT process, microstructure
Ключевые слова: MgB2/Cu, fabrication, densification, joints, pulsed operation, magnetic field dependence, microstructure, MRI magnets
Grasso G., Ferdeghini C., Angurel L.A., Navarro R., Martinez E., Nardelli D., Romano G., Pelegrin J., Brisigotti S.
Ключевые слова: MgB2, tapes multifilamentary, PIT process, MgB2/Ni, MgB2/Cu/Fe, sheath, critical caracteristics, critical current, temperature dependence, resistive transition, resistivity, thermal conductivity, heat capacity, coils pancake, numerical analysis, minimum quench energy, quench propagation, experimental results
Ключевые слова: rotating machines, stators, MgB2/Cu-Ni, coils, design, fabrication, test results, flux density, distribution, quench current, ac losses, cryogenic systems
Tomsic M., Presz A., Surdacki P., Rindfleisch M., Morawski A., Gajda D., Zaleski A., Thong C.J., Cetner T., Malecka M.
Ключевые слова: MgB2/Cu, magnetization, ac losses, tapes monofilamentary, wires multifilamentary, experimental results
Tomsic M., Diduszko R., Presz A., Rindfleisch M., Morawski A., Gajda D., Zaleski A., Adamczyk K., Cetner T.
Ключевые слова: MgB2/Cu-Ni, composites, doping effect, PIT process, tapes, fabrication, critical caracteristics, critical current, composition, Jc/B curves
Ключевые слова: MgB2/Cu, wires, PIT process, doping effect, mechanical properties, loads, hardness, elastic behavior, experimental results
Ключевые слова: MgB2/Cu, MgB2/Monel, wires multifilamentary, joints, joint resistances, experimental results, numerical analysis, comparison
Togano K., Kumakura H., Matsumoto A., Ikeda K., Kubota Y., Hata S., Hur J., Shimada Y., Nakashima H.
Ключевые слова: MgB2/Ta, MgB2/Cu-Ni, fabrication, diffusion process, microstructure, doping effect, critical caracteristics, Jc/B curves, wires multifilamentary
Ключевые слова: MgB2/Cu, MgB2/Fe, wires, conduction cooled systems, pulsed operation, ac losses, experimental results
Holzapfel B., Schultz L., Glowacki B.A., Hopkins S.C., HaBler W., Nenkov K., Rodig C., Schubert M., Morawski A., Herrmann M., Kario A.
Goldacker W., Schlachter S.I., Ringsdorf B., Orschulko H., Jung A., Drechsler A., Runtsch B., Fillinger H.
Syamaprasad U., Vinod K., Varghese N., Kedia S., Pradhan S., Rahul S., Devadas K.M., Thomas S., Gurusamy P.
Ключевые слова: MgB2/Cu, MgB2/Fe, current distribution, electric field distribution, geometry effects, comparison, modeling, numerical analysis, current sharing, length
Holzapfel B., Schultz L., Goldacker W., Schlachter S.I., HaBler W., Nenkov K., Schubert M., Morawski A., Ringsdorf B., Herrmann M., Kario A.
Ключевые слова: MgB2/Cu-Ni, wires, geometry effects, normal zone propagation, level sensor
Ключевые слова: MgB2/Cu/Fe, magnets, conduction cooled systems, quench protection, numerical analysis, MRI magnets
Ключевые слова: MgB2/Cu-Ni, MgB2/Ta, wires multifilamentary, fabrication, Jc/B curves, diffusion process, critical caracteristics
Ключевые слова: MgB2/Cu, PIT process, tapes, fabrication, resistivity, temperature dependence, resistive transition, microstructure, doping effect
Ключевые слова: MgB2/Cu, coils, power equipment, wires, insulation coating, stress effects, CTFF process, microstructure, fabrication
Tomsic M., Sumption M.D., Marzik J.V., Rindfleisch M., Yue J., Finnemore D.K., Lewis R.C., Nickles M.R.
Ключевые слова: switches, HTS, design, YBCO, coated conductors, stabilizing layers, MgB2/Fe, MgB2/Cu, MgB2/Ni, Bi2223/Ag alloy, comparison, tapes, wires, thermal conductivity, specific heat, quench properties, test results
Ключевые слова: MgB2/Cu, wires, critical current, measurement technique, comparison, Jc/B curves, critical caracteristics
Ключевые слова: MgB2/Cu-Ni, tapes, PIT process, nanodoping, precursors, MgB2/Fe, Jc/B curves, fabrication, critical caracteristics
Ключевые слова: MgB2/Nb, MgB2/Cu, MgB2/Cu/Nb, MgB2/Cu/Fe, magnetization curves, hysteresis, sheath, thermomagnetic instability, experimental results, wires, magnetic properties
Ключевые слова: HTS, cables, coated conductors, ac losses, numerical analysis, MgB2/Cu-Ni, wires monofilamentary, wires multifilamentary, YBCO, power equipment
Ключевые слова: MgB2/stainless steel, MgB2/Cu, MgB2/Ti, MgB2/Ag, sheath, doping effect, fabrication, PIT process, microstructure, Jc/B curves, wires, critical caracteristics
Ключевые слова: MgB2/Nb, MgB2/Cu, composites, tapes multifilamentary, barriers, ac losses, PIT process, fabrication, experimental results
Kajikawa K., Funaki K., Hayashi H., Iwakuma M., Kumakura H., Okada M., Tanaka K., Sueyoshi T., Sasashige Y.
Ключевые слова: MgB2/Cu, MgB2/Cu-Ni, barriers, wires multifilamentary, ac losses, experimental results, numerical analysis
Majoros M., Collings E.W., Tomsic M., Sumption M.D., Rindfleisch M., Yue J., Phillips J., Bohnenstiehl S.D.
Syamaprasad U.(syam@csrrltrd.ren.nic.in), Kumar R.G., Vinod K., Varghese N.
Ключевые слова: MgB2/Cu, MgB2/Fe, MgB2/Ni, MgB2/Ta, comparison, sheath, fabrication, tapes
Watanabe K., Koshizuka N., Katagiri K.(katagiri@iwate-u.ac.jp), Kasaba K., Shoji Y., Shimura S., Obara T., Yamakage D.
Ключевые слова: MgB2/Cu alloy, wires, mechanical properties, strain effects, stress effects, experimental results
Majoros M., Campbell A.M., Astill D., Tomsic M., Rindfleisch M., Harrison S., Coombs T., Ye L.(ly231@cam.ac.uk), Husband M.
Ключевые слова: MgB2/Cu, wires, coils, Jc/B curves, power equipment, critical caracteristics
Grasso G., Modica M., Musenich R., Fang H., Salama K., Alessandrini M., Marabotto R., Penco R., Nardelli D., Tassisto M., Liang G., Chang Diaz F.R.
Ключевые слова: MgB2/Cu-Ni, tapes multifilamentary, coils solenoidal, fabrication, quench properties, power equipment
Ключевые слова: MgB2, doping effect, sheath, MgB2/Fe, MgB2/Cu, MgB2/Ta, composition, comparison, critical current density, PIT process, fusion magnets, fabrication, critical caracteristics, high field magnets
Majoros M., Collings E.W., Tomsic M., Sumption M.D., Rindfleisch M., Buta F., Yue J., Phillips J., Kawabata S., Bohnenstichl S.
Ключевые слова: MgB2/Cu, tapes, nanodoping, pinning, irreversibility fields, fabrication, PIT process, Jc/B curves, critical caracteristics, magnetic properties
Ключевые слова: patents, MgB2, powder metallurgy, powder processing, MgB2/Cu, wires, fabrication, Jc/B curves, precursors, PIT process, CVD process, coatings, critical caracteristics
Glowacki B.A.(bag10@cam.ac.uk), Majoros M., Kitaguchi H., Kumakura H., Okada M., Tanaka K., Yamada H., Hirakawa M*4., Hancock M.H., Bay N.
Ключевые слова: MgB2/Cu, phase formation, fabrication, phase diagram
Obst B., Goldacker W., Liu B., Schlachter S.I.(sonja.schlachter@itp.fzk.de), Frank A., Ringsdorf B., Orschulko H.
Tanaka S., Koshizuka N., Nakao K., Shimura S.(shimura@istec.or.jp), Machi T., Mochizuki K., Shibata N., Ushio K.
Ключевые слова: MgB2/Cu, wires, PIT process, MgB2, coatings, current-voltage characteristics, microstructure, Jc/B curves, coils, fabrication, power equipment, critical caracteristics
Osamura K., Nakamura T., Okada M., Higashikawa K.(kohei@asl.kuee.kyoto-u.ac.jp), Takahashi M.
Kobayashi H., Mizuno K.(mizutti10@hotmail.com), Uchiyama D., Maeda M., Akao T., Kawakami T., Kubota Y., Yasohama K.
Ключевые слова: MgB2/Cu, fabrication, microstructure, critical current density, temperature dependence, critical caracteristics
Tomsic M., Sumption M.D., Bhatia M., Rindfleisch M., Phillips J., Collings E.W.(ted@osu.edu)
Kovac P., Husek I., Diduszko R., Pachla W.(wacek@unipress.waw.pl), Presz A.
Ключевые слова: MgB2/Cu, MgB2/Fe, wires multifilamentary, microstructure, fabrication
Husek I., Kovac P.(elekkova@savba.sk), Melisek T., Grivel J.C., Pachla W., Strbik V., Diduszko R., Homeyer J., Andersen N.H.
Kilic A., Okur S., Guclu N.(guclu06@hotmail.com), Kolemen U., Uzun O., Ozyuzer L., Gencer A.
Ключевые слова: MgB2/Cu, susceptibility, ac losses, temperature dependence, numerical analysis, experimental results, magnetic properties
Holzapfel B., Schultz L., Perner O., Eckert J., Fischer C., Nenkov K., Habler W.(w.haessler@ifw-dresden.de), Rodig C., Behr G., Schubert M.
Collings E.W., Tomsic M., Sumption M.D., Bhatia M.(bhatia.27@osu.edu)
Ключевые слова: MgB2/Fe, MgB2/Cu, MgB2/Fe alloy, wires, heat treatment, Jc/B curves, experimental results, critical caracteristics
Murakami M., Koshizuka N., Shimura S.(shimura@istec.or.jp), Machi T., Mochizuki K., Ishikawa I., Shibata N.
Ключевые слова: MgB2/Cu, wires, PIT process, fabrication, Jc/B curves, coils, current-voltage characteristics, power equipment, critical caracteristics
Dou S.X., Soltanian S., Wang X.L., Kusevic I.(ikusevic@phy.hr), Babic E., Husnjak O.
Matsushita T., Otabe E.S., Kiuchi M.(kiuchi@cse.kyutech.ac.jp), Kitaguchi H., Kumakura H., Okada M., Tanaka K., Yamauchi K., Kurokawa T.
Glowacki B.A.(bag10@cam.ac.uk), Majoros M., Vickers M., Eisterer M., Toenies S., Weber H.W., Fukutomi M., Komori K., Togano K.
Glowacki B.A.(bag10@cam.ac.uk), Majoros M., Eisterer M., Toenies S., Weber H.W., Fukutomi M., Komori K., Togano K.
Ключевые слова: MgB2/Cu, PIT process, coated conductors, Bi2212, substrate Hastelloy, substrate Ag, Jc/B curves, pinning force, review, HTS, critical caracteristics, fabrication, magnetic properties
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