Ключевые слова: magnets dipole, LTS, NbTi, wires, quench protection, resistor, design, heat capacity, thermal conductivity, thermal expansion, experimental results
Ключевые слова: HTS, REBCO, cables, magnets, quench properties, heat capacity, temperature dependence, thermal conductivity, modeling, numerical analysis
Ключевые слова: REBCO, coated conductors, cable-in-conduit conductor, design parameters, fusion magnets, heat capacity, critical current, angular dependence, quench properties, thermal-hydraulics, normal zone propagation, RRR parameter, twist-pitch, contact characteristics, resistance, n-value, magnetic field dependence, HTS
Ключевые слова: HTS, YBCO, coated conductors, modeling, current, dc performance, ac magnetic field dependence, quench, recovery characteristics, losses, dynamic resistance, shielding effects, frequency dependence, stabilizing layers, Cu-based conductors, thermal conductivity, heat capacity, design parameters, critical caracteristics, critical current, distribution, temperature dependence, current distribution, resistance, heat transfer, experimental results
Ключевые слова: HTS, YBCO, fabrication, sol gel process, mechanical treatment, annealing process, susceptibility, magnetization, heat capacity
Ключевые слова: HTS, YBCO, fabrication, phase formation, phase composition, X-ray diffraction, microstructure, heat capacity
Ключевые слова: LTS, Nb3Sn, wires multifilamentary, doping effect, heat capacity, stability, RRR parameter, flux pumps, quench energy, magnetization, microstructure, experimental results
Ключевые слова: HTS, coils pancake, insulationless, design parameters, thermal stability, mechanical properties, quench, modeling, thermal conductivity, temperature dependence, heat capacity, current distribution, stress distribution, strain effects, pulsed operation, geometry effects, recovery characteristics
Ключевые слова: LTS, Nb3Sn, wires multifilamentary, composites, fabrication, doping effect, heat capacity, stability, magnets, HTS, review
Ключевые слова: fusion magnets, high field magnets, forced flow, cooling technology, hydrogen, helium, neon, heat transfer, coils toroidal, HTS, REBCO, cables, current sharing, heat capacity, pressure drop, modeling, numerical analysis
Ключевые слова: HTS, YBCO, bulk, heat capacity, thermal stability, microstructure, experimental results
Akimov I.I., Keilin V.E., Kovalev I.A., Kruglov S.L., Shutova D.I., Kriukov D.A., Titov A.O., Shkolin S.A.
Ключевые слова: LTS, NbTi, Rutherford cables, fabrication, coatings, microstructure, heat capacity, stability
Keilin V.E., Kovalev I.A., Kruglov S.L., Potanina L.V., Shutova D.I., Salunin N.I., Vorobjeva A.E., Sсherbakov V.I.
Ключевые слова: Nb3Sn, Nb3Ge, LTS, lattice parameter, phase diagram, heat capacity, upper critical fields, Nb3Al, Nb3Ga, review
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: cryocoolers, cryogenic systems, heat capacity, numerical analysis
Ключевые слова: HTS, YBCO, coated conductors, coils pancake, numerical analysis, modeling, quench propagation, thermal properties, thermal conductivity, heat capacity, temperature dependence, normal zone propagation, recovery characteristics, minimum quench energy, bulk, pulsed magnetization, trapped field distribution, new
Godeke A., Goldacker W., Dietderich D.R., Sumption M.D., Susner M.A., Dhalle M.M., Mentink M.G., Hellman F., Kate H.H.
Ключевые слова: nitrogen solid, cooling technology, cryostability, heat capacity, experimental results
Shikov A.K., Keilin V.E., Kovalev I.A., Medvedev M.I., Kruglov S.L., Potanina L.V., Shutova D.I., Salunin N.I., Vorobjeva A.E., Iljin A.A., Naumov A.V.
Ключевые слова: LTG process, NbTi, coils, composites, doping effect, heat capacity, stability, experimental results, numerical analysis, quench energy
Ключевые слова: cryogenic systems, nitrogen solid, NMR magnet, MRI magnets, LTS, Nb3Sn, MgB2, NbTi, HTS, YBCO, bulk, rings, heat capacity, neon, argon
Ключевые слова: HTS, magnets, cryogenic systems, cryogenic materials, heat capacity, vehicle applications, experimental results
Godeke A., Goldacker W., Dietderich D.R., Sumption M.D., Susner M.A., Dhalle M.M., Mentink M.G., Anders A., Hellman F., Putnam D., Slack J.L., ten Kate H.
Lin L.Z., Dai S.T., Qiu M., Xiao L.Y., Wang Z.K., Li X.H., Zhang G.M., Song N.H., Zhang J.Y., Zhang D., Zhang Z.F., Du X.J., Zhang F.Y., Zhou W.W.
Ключевые слова: MgB2, wires multifilamentary, critical caracteristics, critical current, temperature dependence, quench propagation, minimum quench energy, MRI magnets, design parameters, fabrication, stability, thermal conductivity, resistance, heat capacity, current-voltage characteristics, experimental results
Shikov A.K., Keilin V.E., Kovalev I.A., Medvedev M.I., Kruglov S.L., Shutova D.I., Salunin N.I., Vorobjeva A.E., Potanina L.V.*21
Ключевые слова: LTS, NbTi, doping effect, heat capacity, wires multifilamentary, experimental results, fabrication, composites, critical caracteristics, coils, quench current, magnets, stability
Ключевые слова: HTS, YBCO, coated conductors, stabilizing layers, quench properties, recovery characteristics, nitrogen solid, heat capacity, cryogenic systems, conduction cooled systems, overcurrent, critical caracteristics, current-voltage characteristics, thermal stability, stability, experimental results
Ключевые слова: refrigerator, cryogenic systems, hydrogen liquid, calorimetric method, heat capacity
Круглов С.Л., Кейлин В.Е., Ковалев И.А., Шутова Д.И., Щербаков В.И.(sherby@isssph.kiae.ru)
Ключевые слова: LTS, NbTi, stability, heat capacity, coil spacers, experimental results, power equipment
Круглов С.Л., Кейлин В.Е., Ковалев И.А., Медведев М.И., Шутова Д.И., Шиков А.К., Воробьева А.Е., Потанина Л.В., Салунин Н.И.
Ключевые слова: LTS, NbTi, coils solenoidal, winding techniques, stability, reinforcement, insulating medium, doping effect, heat capacity, experimental results, power equipment
Ключевые слова: LTS, NbTi, stability, heat capacity, coil spacers, experimental results, coils solenoidal, training effect, power equipment
Ключевые слова: LTS, NbTi, coils solenoidal, winding techniques, stability, reinforcement, insulating medium, doping effect, heat capacity, experimental results, power equipment
Shikov A.K., Vorobieva A.E., Keilin V.E., Kovalev I.A., Medvedev M.I., Kruglov S.L., Potanina L.V., Salunin N.I.
Ключевые слова: LTS, Nb3Sn, NbTi, wires multifilamentary, heat capacity, insulating medium, fabrication, experimental results, critical caracteristics
Круглов С.Л., Кейлин В.Е.(kev@isssph.kiae.ru), Алексеев П.А., Ковалев И.А., Лазуков В.Н., Медведев М.И., Шутова Д.И.
Ключевые слова: LTS, NbTi, stability, heat capacity, coil spacers, experimental results, power equipment
Keilin V.E., Kovalev I.A., Medvedev M.I., Kruglov S.L., Lazukov V.N., Shutova D.I., Alekseev P.A.(kev@isssph.kiae.ru)
Ключевые слова: LTS, NbTi, composites, heat capacity, PIT process, stabilizing layers, experimental results, insulating medium, fabrication
Lee P.J.(lee@engr.wisc.edu), Larbalestier D.C., Hawes C.D.
Boev A.I., Kovalev I.A., Alekseev P.A., Keilin V.E.(kev@isssph.kiae.ru), Kruglov S.L., Lazukov V.N., Sadikov I.P., Kozub S.S., Kostrov E.A., Shutova D.I.
Ключевые слова: LTS, NbTi, strands, winding techniques, Rutherford cables, insulating medium, heat capacity, quench current, experimental results, power equipment
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