Papers Published in 2019

Here below are some review publications related to analytical and numerical models of superconductors. Some of them are a concrete results of the collaborative effort of this work group.

This page is updated periodically. Please help us to find your paper just adding “HTS Modelling” to keywords of your manuscript. Do not hesitate to suggest additional references that might have been forgotten below directly to the Webmaster.

LIST OF PAPERS

  • [DOI] N. Amemiya, Y. Sogabe, S. Yamano, and H. Sakamoto, “Shielding current in a copper-plated multifilament coated conductor wound into a single pancake coil and exposed to a normal magnetic field,” Superconductor Science and Technology, vol. 32, iss. 11, p. 115008, 2019.
    [Bibtex]
    @article{Amemiya:SST19,
      Abstract = {A single pancake coil wound with a copper-plated multifilament coated conductor, with four filaments, was put in a cusp magnetic field, and the magnetic field was measured near the coil at 30 K. A similar experiment was performed by using another reference single pancake coil wound with a monofilament coated conductor. Numerical electromagnetic field analyses of these coils were carried out, and the calculated shielding current-induced fields (SCIFs) were compared with the measured ones in both coils. The temporal behaviour of the calculated SCIF in the coil wound with the four-filament coated conductor was also compared with a series of exponential components, in which a coupling time constant extrapolated from short sample experiments was used as the time constant of the primary component. Current distributions in the coated conductors wound into the pancake coils were visualised. In particular, the temporal behaviours of the current distributions in the four-filament coated conductor and their influence on the SCIF were discussed.},
      Author = {N. Amemiya and Y. Sogabe and S. Yamano and H. Sakamoto},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1088/1361-6668/ab3f1c},
      Journal = {Superconductor Science and Technology},
      Number = {11},
      Pages = {115008},
      Title = {{Shielding current in a copper-plated multifilament coated conductor wound into a single pancake coil and exposed to a normal magnetic field}},
      Url = {https://doi.org/10.1088%2F1361-6668%2Fab3f1c},
      Volume = {32},
      Year = 2019}
  • [DOI] A. Colle, T. Lubin, S. Ayat, O. Gosselin, and J. Lévêque, “Analytical Model for the Magnetic Field Distribution in a Flux Modulation Superconducting Machine,” IEEE Transactions on Magnetics, vol. 55, iss. 12, pp. 1-9, 2019.
    [Bibtex]
    @article{Colle:2019,
    author={A. {Colle} and T. {Lubin} and S. {Ayat} and O. {Gosselin} and J. {Lévêque}},
    journal={IEEE Transactions on Magnetics},
    title={{Analytical Model for the Magnetic Field Distribution in a Flux Modulation Superconducting Machine}},
    year={2019},
    volume={55},
    number={12},
    pages={1-9},
    keywords={Analytical model;axial field machine;high-temperature superconductors (HTSs);synchronous machine},
    doi={10.1109/TMAG.2019.2935696},
    ISSN={1941-0069},
    month={Dec}}
  • [DOI] F. Gu, W. Li, L. Zhong, X. Duan, M. Song, Z. Li, Z. Hong, and Z. Jin, “Study on Magnetization Losses in Soldered-Stacked-Square (3S) HTS Wires with 1 mm Width,” Journal of Superconductivity and Novel Magnetism, 2019.
    [Bibtex]
    @article{Gu:JSNM19,
      Abstract = {Magnetization loss of high-temperature superconducting (HTS) wires is usually considered as a critical issue in power applications. In order to reduce magnetization loss, a narrow soldered-stacked-square (3S) HTS wire with 1 mm width is firstly proposed by our group. And as a novel HTS wire type, its magnetization loss should be significantly understood before applied in further application. In this study, we fabricate the 1-mm-wide 3S wires with 2+4c, 4+2c, and 6+0c structures, and evaluate their magnetization loss experimentally and numerically. In the fabrication process of the 3S wires, a newly suggested technology, laser cutting, is adopted. The results show that the magnetization loss in (4+2c)-wire is independent of the frequency under perpendicular field but dependent on the frequency under parallel field. This may be considered that both eddy current loss and coupling loss are contained in the case of parallel field, besides hysteresis loss. Moreover, the different structures of the 3S wires will not affect the magnetization loss under perpendicular fields, but influence the magnetization loss under parallel fields. And these numerical results for parallel field have larger deviations compared with measured magnetization loss because only hysteresis loss is considered in the numerical model. Finally, a considerable reduction of the magnetization loss in the 3S wire is observed in the comparison with that in the original tape.},
      Author = {F. Gu and W. Li and L. Zhong and X. Duan and M. Song and Z. Li and Z. Hong and Z. Jin},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1007/s10948-019-05151-3},
      Journal = {Journal of Superconductivity and Novel Magnetism},
      Title = {{Study on Magnetization Losses in Soldered-Stacked-Square (3S) HTS Wires with 1 mm Width}},
      Url = {https://doi.org/10.1007/s10948-019-05151-3},
      Year = {2019}}
  • [DOI] Y. Higashi and Y. Mawatari, “Electromagnetic coupling of twisted multi-filament superconducting tapes in a ramped magnetic field,” Superconductor Science and Technology, vol. 32, iss. 5, p. 055010, 2019.
    [Bibtex]
    @article{Higashi:SST19,
      Abstract = {We theoretically investigate the magnetization loss and electromagnetic coupling of twisted multi-filament superconducting (SC) tapes in a ramped magnetic field. Based on the two-dimensional reduced Faraday--Maxwell equation for a tape surface obtained with a thin-sheet approximation, we numerically simulate the power loss P per unit length on twisted multi-filament tapes in the steady state. The current density profile clearly shows electromagnetic coupling between the SC filaments upon increasing the field sweep rate ?. Although the ? dependence of  for twisted multi-filament SC tapes closely resembles that for filaments in an alternating field, we show that the mechanism for electromagnetic coupling in a ramped field differs from that in an alternating field. We also identify the conditions under which electromagnetic coupling is suppressed for the typical sweep rate of a magnet used for magnetic resonance imaging.},
      Author = {Y. Higashi and Y. Mawatari},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1088/1361-6668/ab0d63},
      Journal = {Superconductor Science and Technology},
      Number = {5},
      Pages = {055010},
      Title = {{Electromagnetic coupling of twisted multi-filament superconducting tapes in a ramped magnetic field}},
      Url = {https://doi.org/10.1088%2F1361-6668%2Fab0d63},
      Volume = {32},
      Year = 2019}
  • [DOI] Y. Higashi, H. Zhang, and Y. Mawatari, “Analysis of Magnetization Loss on a Twisted Superconducting Strip in a Constantly Ramped Magnetic Field,” IEEE Transactions on Applied Superconductivity, vol. 29, iss. 1, p. 8200207, 2019.
    [Bibtex]
    @article{Higashi:TAS19,
      Author = {Y. Higashi and H. Zhang and Y. Mawatari},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:48:16 +0200},
      Doi = {10.1109/TASC.2018.2874481},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {1},
      Pages = {8200207},
      Title = {{Analysis of Magnetization Loss on a Twisted Superconducting Strip in a Constantly Ramped Magnetic Field}},
      Url = {https://doi.org/10.1109/TASC.2018.2874481},
      Volume = {29},
      Year = {2019}}
  • [DOI] B. E. Juarez, V. M. R. Zermeño, F. Trillaud, and F. Grilli, “Real-time simulation of large-scale HTS systems: multi-scale and homogeneous models using $T-A$ formulation,” Superconductor Science and Technology, vol. 32, iss. 6, p. 065003, 2019.
    [Bibtex]
    @article{BerrospeJuarez:SST19,
      Author = {E. Berrospe Juarez and V. M. R. Zerme\~no and F. Trillaud and F. Grilli},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1088/1361-6668/ab0d66},
      Journal = {Superconductor Science and Technology},
      Number = {6},
      Pages = {065003},
      Title = {{Real-time simulation of large-scale HTS systems: multi-scale and homogeneous models using $T-A$ formulation}},
      Url = {https://doi.org/10.1088/1361-6668/ab0d66},
      Volume = {32},
      Year = {2019}}
  • [DOI] Y. Liu, J. Ou, F. Grilli, F. Schreiner, V. M. R. Zermeño, M. Zhang, and M. Noe, “Comparison of 2D simulation models to estimate the critical current of a coated superconducting coil,” Superconductor Science and Technology, vol. 32, iss. 1, p. 014001, 2019.
    [Bibtex]
    @article{Liu:SST19,
      Author = {Y. Liu and J. Ou and F. Grilli and F. Schreiner and V. M. R. Zerme\~no and M. Zhang and M. Noe},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1088/1361-6668/aae960},
      Journal = {Superconductor Science and Technology},
      Number = {1},
      Pages = {014001},
      Title = {{Comparison of 2D simulation models to estimate the critical current of a coated superconducting coil}},
      Url = {https://doi.org/10.1088/1361-6668/aae960},
      Volume = {32},
      Year = {2019}}
  • [DOI] Y. Mawatari, “Theoretical evaluation of the screening-current-induced magnetic field in superconducting coils with tape wires,” Applied Physics Express, vol. 12, iss. 1, p. 013002, 2019.
    [Bibtex]
    @article{Mawatari:APE19,
      Abstract = {We theoretically investigate the physical mechanism of the screening-current-induced field (SCIF) in solenoid coils wound with superconducting tape wires. We derive the direct relationship between the SCIF and the magnetization of tape wires, and a scaling law for the SCIF and the coil dimensions is demonstrated. A simple analytical expression of the SCIF is obtained as functions of current load factor, tape wire width, and the coil dimensions. We verify that the published data for the precise numerical computation of SCIF are roughly fitted by our theoretical results for flat coils where the height is smaller than the outer diameter.},
      Author = {Y. Mawatari},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.7567/1882-0786/aaf171},
      Journal = {Applied Physics Express},
      Number = {1},
      Pages = {013002},
      Title = {{Theoretical evaluation of the screening-current-induced magnetic field in superconducting coils with tape wires}},
      Url = {https://doi.org/10.7567/1882-0786/aaf171},
      Volume = {12},
      Year = {2019}}
  • [DOI] E. Pardo, F. Grilli, Y. Liu, S. Wolftaedler, and T. Reis, “AC Loss Modelling in Superconducting Coils and Motors with Parallel Tapes as Conductor,” IEEE Transactions on Applied Superconductivity, vol. 29, iss. 5, 2019.
    [Bibtex]
    @article{Pardo:TAS19,
      Author = {E. Pardo and F. Grilli and Y. Liu and S. Wolftaedler and T. Reis},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1109/TASC.2019.2899148},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {5},
      Title = {{AC Loss Modelling in Superconducting Coils and Motors with Parallel Tapes as Conductor}},
      Url = {https://doi.org/10.1109/TASC.2019.2899148},
      Volume = {29},
      Year = {2019}}
  • [DOI] S. S. Peng, J. Zheng, W. Y. Li, and Y. J. Dai, “AC Loss Analysis of a Single-Solenoid HTS SMES Based on H-formulation,” IOP Conference Series: Earth and Environmental Science, vol. 233, p. 022018, 2019.
    [Bibtex]
    @article{Peng:IOPCS19,
      Abstract = {There will be much AC loss generated when a superconducting magnetic energy storage(SMES) is applied in a power system to exchange power with a power network or other equipment. AC loss may cause the instability and risk of burnout to SMES. This paper presents a commonly used SMES design scheme and lists the design parameters of a 10MJ/5MW SMES. We used the finite element software COMSOL to build a simulation model to calculate the AC loss during its operation. We get the calculated results and analyse AC loss`s distribution characteristics of the 10MJ/5MW SMES which uses a single screw structure.},
      Author = {S. S. Peng and J. Zheng and W. Y. Li and Y. J. Dai},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1088/1755-1315/233/2/022018},
      Journal = {IOP Conference Series: Earth and Environmental Science},
      Pages = {022018},
      Title = {{AC Loss Analysis of a Single-Solenoid HTS SMES Based on H-formulation}},
      Url = {https://doi.org/10.1088/1755-1315/233/2/022018},
      Volume = {233},
      Year = 2019}
  • [DOI] A. N. Petrov, J. A. Pilgrim, and I. O. Golosnoy, “Revisiting the homogenized domain model for fast simulation of AC transport power losses in first generation high temperature superconducting tapes and cables,” Physica C, vol. 557, pp. 33-40, 2019.
    [Bibtex]
    @article{Petrov:PhysC19,
      Abstract = {Challenges, linked with FEM modelling of HTS power cables, include the long computational time required to simulate the small domains that Bi-2223 superconductors possess in a large device. To decrease that time, in this paper the models of AC transport power losses for a tape and a simplified cable are achieved by a homogenization technique via a ''filamentary-equivalent domain'' approach. In it, a single homogenous domain with effective material properties is used to represent the superconducting material, where the domain would have the approximate shape of the multifilamentary region. In order to investigate its validity for a range of transport currents, including overcurrent, four tapes from the literature are modelled in three configurations. A simplified cable model is modelled via the homogenized model and an analytical equivalent circuit model. The homogenization technique can accurately predict the transport power losses of the majority of configurations while demonstrating fast computational times and is promising for simulation of real power cables.},
      Author = {A. N. Petrov and J.A. Pilgrim and I. O. Golosnoy},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {https://doi.org/10.1016/j.physc.2018.12.006},
      Issn = {0921-4534},
      Journal = {Physica C},
      Pages = {33-40},
      Title = {{Revisiting the homogenized domain model for fast simulation of AC transport power losses in first generation high temperature superconducting tapes and cables}},
      Volume = {557},
      Year = {2019}}
  • [DOI] N. Riva, S. Richard, F. Sirois, C. Lacroix, B. Dutoit, and F. Grilli, “Over-Critical Current Resistivity of YBCO Coated Conductors through Combination of Pulsed Current Measurements and Finite Element Analysis,” IEEE Transactions on Applied Superconductivity, vol. 29, iss. 5, p. 6601705, 2019.
    [Bibtex]
    @article{Riva:TAS19,
      Author = {N. Riva and S. Richard and F. Sirois and C. Lacroix and B. Dutoit and F. Grilli},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1109/TASC.2019.2902038},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {5},
      Pages = {6601705},
      Title = {{Over-Critical Current Resistivity of YBCO Coated Conductors through Combination of Pulsed Current Measurements and Finite Element Analysis}},
      Url = {https://doi.org/10.1109/TASC.2019.2902038},
      Volume = {29},
      Year = {2019}}
  • [DOI] B. C. Robert, M. U. Fareed, and H. S. Ruiz, “How to Choose the Superconducting Material Law for the Modelling of 2G-HTS Coils,” Materials, vol. 12, iss. 17, p. 2679, 2019.
    [Bibtex]
    @article{Robert19,
      author   = {Bright Chimezie Robert and Muhammad Umar Fareed and Harold Steven Ruiz},
      Title   = {{How to Choose the Superconducting Material Law for the Modelling of 2G-HTS Coils}},
      journal = {Materials},
      volume   = {12},
      Number   = {17},
      year   = {2019},
      doi   = {10.3390/ma12172679},
      pages   = {2679},
      url   = {https://doi.org/10.3390/ma12172679},
    }
  • [DOI] B. Shen, T. A. Coombs, and F. Grilli, “Investigation of AC Loss in HTS Cross-Conductor Cables for Electrical Power Transmission,” IEEE Transactions on Applied Superconductivity, vol. 29, iss. 2, p. 5900205, 2019.
    [Bibtex]
    @article{Shen:TAS19,
      Author = {B. Shen and T. A. Coombs and F. Grilli},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1109/TASC.2018.2881491},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {2},
      Pages = {5900205},
      Title = {{Investigation of AC Loss in HTS Cross-Conductor Cables for Electrical Power Transmission}},
      Url = {https://doi.org/10.1109/TASC.2018.2881491},
      Volume = {29},
      Year = {2019}}
  • [DOI] F. Sirois, F. Grilli, and A. Morandi, “Comparison of Constitutive Laws for Modeling High-Temperature Superconductors,” IEEE Transactions on Applied Superconductivity, vol. 29, iss. 1, p. 8000110, 2019.
    [Bibtex]
    @article{Sirois:TAS19,
      Author = {F. Sirois and F. Grilli and A. Morandi},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1109/TASC.2018.2848219},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {1},
      Pages = {8000110},
      Title = {{Comparison of Constitutive Laws for Modeling High-Temperature Superconductors}},
      Url = {https://doi.org/10.1109/TASC.2018.2848219},
      Volume = {29},
      Year = {2019}}
  • [DOI] G. Vyas and R. S. Dondapati, “AC losses in the development of superconducting magnetic energy storage devices,” Journal of Energy Storage, vol. 27, p. 101073, 2020.
    [Bibtex]
    @article{Vyas:2020,
    title = "AC losses in the development of superconducting magnetic energy storage devices",
    journal = "Journal of Energy Storage",
    volume = "27",
    pages = "101073",
    year = "2020",
    issn = "2352-152X",
    doi = "https://doi.org/10.1016/j.est.2019.101073",
    url = "http://www.sciencedirect.com/science/article/pii/S2352152X19313854",
    author = "Gaurav Vyas and Raja Sekhar Dondapati",
    }
  • [DOI] Y. Wang, M. Zhang, F. Grilli, Z. Zhu, and W. Yuan, “Study of the magnetization loss of CORC cables using 3D T-A formulation,” Superconductor Science and Technology, vol. 32, iss. 2, p. 025003, 2019.
    [Bibtex]
    @article{Wang:SST19,
      Author = {Y. Wang and M. Zhang and F. Grilli and Z. Zhu and W. Yuan},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1088/1361-6668/aaf011},
      Journal = {Superconductor Science and Technology},
      Number = {2},
      Pages = {025003},
      Title = {{Study of the magnetization loss of CORC cables using 3D T-A formulation}},
      Url = {https://doi.org/10.1088/1361-6668/aaf011},
      Volume = {32},
      Year = {2019}}
  • [DOI] J. Wu, H. Yong, and Y. Zhou, “Numerical estimation of AC losses in Bi2212/Ag wire and coil,” Physica C, 2019.
    [Bibtex]
    @article{Wu:PhysC19,
      Abstract = {The multi-filamentary Bi2Sr2CaCu2O8-x (Bi2212) round wire is the candidate for high field magnets, which is macroscopically isotropic and has large critical current in high field. AC losses generated in coils by ac transport current and magnetic field will lead to the rise of local temperature and consumption of liquid helium. However, the simulations of AC losses in coils are limited by the complicated geometry. This paper presents a homogenization model for computing the current density distributions, field distributions and AC losses in coils wound by multifilament Bi2212/Ag round wire. Based on two-dimensional axisymmetric H-formulation (H is the magnetic filed), the field dependent critical current density and the nonlinear relation between the electric filed E and the current density J are used to describe the macroscopic behavior of the superconductor. To validate the homogenization model, the AC loss is compared with the result of origin model which has the actual filament configuration of round wire. The homogenization model is powerful to estimate the AC losses of cables and coils made by Bi2212/Ag round wire.},
      Author = {J. Wu and H. Yong and Y. Zhou},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1016/j.physc.2019.05.005},
      Journal = {Physica C},
      Title = {{Numerical estimation of AC losses in Bi2212/Ag wire and coil}},
      Url = {https://doi.org/10.1016/j.physc.2019.05.005},
      Year = {2019}}
  • [DOI] Y. Yan, P. Song, S. Jiang, J. Zhu, H. Zhang, Y. Zhu, R. Liu, Y. Li, F. Feng, M. Zhang, and T. Qu, “Experimental and Numerical Study on the Magnetization Process of Roebel Cable Segments,” IEEE Transactions on Applied Superconductivity, vol. 29, iss. 8201005, 2019.
    [Bibtex]
    @article{Yan:TAS19,
      Author = {Y. {Yan} and P. {Song} and S. {Jiang} and J. {Zhu} and H. {Zhang} and Y. {Zhu} and R. {Liu} and Y. {Li} and F. {Feng} and M. {Zhang} and T. {Qu}},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1109/TASC.2019.2900981},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {8201005},
      Title = {Experimental and Numerical Study on the Magnetization Process of Roebel Cable Segments},
      Url = {https://doi.org/10.1109/TASC.2019.2900981},
      Volume = {29},
      Year = {2019}}
  • [DOI] J. Zheng, S. S. Peng, W. Y. Li, and Y. J. Dai, “Magnet design of 10 MJ multiple solenoids SMES,” IOP Conference Series: Earth and Environmental Science, vol. 233, p. 032026, 2019.
    [Bibtex]
    @article{Zheng_IOPCS19,
      Abstract = {The superconducting magnetic energy storage system uses the superconducting coil to store the energy of the grid in the form of electromagnetic energy, and then release the electromagnetic energy to the power grid or other devices when needed. Compared with other energy storage technologies, superconducting magnetic energy storage systems have the advantages of fast response, adjustable active and reactive four quadrants, it can improve the stability and quality of power system, and be used for dispersion in power systems, power system and energy management. This paper mainly introduces the magnet design of four-screw SMES in 10 MJ class, including performance analysis, modular and parallel design scheme and AC loss calculation.},
      Author = {J. Zheng and S. S. Peng and W. Y. Li and Y. J. Dai},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {file:///Users/yz4567/Documents/Articles/pdfs/Zheng_IOPCS19.pdf},
      Journal = {IOP Conference Series: Earth and Environmental Science},
      Pages = {032026},
      Title = {{Magnet design of 10 MJ multiple solenoids SMES}},
      Url = {https://doi.org/10.1088/1755-1315/233/3/032026},
      Volume = {233},
      Year = {2019}}
  • [DOI] P. Zhou, G. Ma, and L. Quéval, “Transition frequency of transport ac losses in high temperature superconducting coated conductors,” Journal of Applied Physics, vol. 126, iss. 6, p. 063901, 2019.
    [Bibtex]
    @article{Zhou:JAP19,
      Author = {P. Zhou and G. Ma and L. Qu{\'e}val},
      Date-Added = {2019-10-15 14:45:14 +0200},
      Date-Modified = {2019-10-15 14:45:14 +0200},
      Doi = {10.1063/1.5094727},
      Journal = {Journal of Applied Physics},
      Number = {6},
      Pages = {063901},
      Title = {{Transition frequency of transport ac losses in high temperature superconducting coated conductors}},
      Url = {http://doi.org/10.1063/1.5094727},
      Volume = {126},
      Year = {2019}}

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Events

  • 7th International Workshop on Numerical Modelling of HTS.