Papers Published in 2016

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] M. D. Ainslie, D. Zhou, H. Fujishiro, K. Takahashi, Y. -H. Shi, and J. H. Durrell, “Flux jump-assisted pulsed field magnetisation of high-Jc bulk high-temperature superconductors,” Superconductor Science and Technology, vol. 29, iss. 12, p. 124004, 2016.
    [Bibtex]
    @article{Ainslie:SST16,
      Abstract = {Investigating, predicting and optimising practical magnetisation techniques for charging bulk superconductors is a crucial prerequisite to their use as high performance `psuedo' permanent magnets. The leading technique for such magnetisation is the pulsed field magnetisation (PFM) technique, in which a large magnetic field is applied via an external magnetic field pulse of duration of the order of milliseconds. Recently `giant field leaps' have been observed during charging by PFM: this effect greatly aids magnetisation as flux jumps occur in the superconductor leading to magnetic flux suddenly intruding into the centre of the superconductor. This results in a large increase in the measured trapped field at the centre of the top surface of the bulk sample and full magnetisation. Due to the complex nature of the magnetic flux dynamics during the PFM process, simple analytical methods, such as those based on the Bean critical state model, are not applicable. Consequently, in order to successfully model this process, a multi-physical numerical model is required, including both electromagnetic and thermal considerations over short time scales. In this paper, we show that a standard numerical modelling technique, based on a 2D axisymmetric finite-element model implementing the H -formulation, can model this behaviour. In order to reproduce the observed behaviour in our model all that is required is the insertion of a bulk sample of high critical current density, J c . We further explore the consequences of this observation by examining the applicability of the model to a range of previously reported experimental results. Our key conclusion is that the `giant field leaps' reported by Weinstein et al and others need no new physical explanation in terms of the behaviour of bulk superconductors: it is clear the `giant field leap' or flux jump-assisted magnetisation of bulk superconductors will be a key enabling technology for practical applications.},
      Author = {M. D. Ainslie and D. Zhou and H. Fujishiro and K. Takahashi and Y.-H. Shi and J. H. Durrell},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1088/0953-2048/29/12/124004},
      Journal = {Superconductor Science and Technology},
      Number = {12},
      Pages = {124004},
      Title = {{Flux jump-assisted pulsed field magnetisation of high-Jc bulk high-temperature superconductors}},
      Url = {https://doi.org/10.1088/0953-2048/29/12/124004},
      Volume = {29},
      Year = {2016}}
  • [DOI] B. J. H. de Bruyn, J. W. Jansen, and E. A. Lomonova, “Finite Element Model Simplification Methods for Stacks of Superconducting Tapes,” IEEE Transactions on Magnetics, vol. 52, iss. 7, p. 9000104, 2016.
    [Bibtex]
    @article{deBruyn:TMAG16,
      Author = {B. J. H. de Bruyn and J. W. Jansen and E. A. Lomonova},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TMAG.2016.2529006},
      Journal = {IEEE Transactions on Magnetics},
      Number = {7},
      Pages = {9000104},
      Title = {{Finite Element Model Simplification Methods for Stacks of Superconducting Tapes}},
      Url = {http://doi.org/10.1109/TMAG.2016.2529006},
      Volume = {52},
      Year = {2016}}
  • [DOI] G. Escamez, F. Sirois, A. Badel, G. Meunier, B. Ramdane, and P. Tixador, “Numerical Impact of Using Different E-J Relationships for 3-D Simulations of AC Losses in MgB2 Superconducting Wires,” IEEE Transactions on Magnetics, vol. 52, iss. 3, p. 7402904, 2016.
    [Bibtex]
    @article{Escamez:TMAG16,
      Author = {G. Escamez and F. Sirois and A. Badel and G. Meunier and B. Ramdane and P. Tixador},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TMAG.2015.2480960},
      Journal = {IEEE Transactions on Magnetics},
      Number = {3},
      Pages = {7402904},
      Title = {{Numerical Impact of Using Different E-J Relationships for 3-D Simulations of AC Losses in MgB2 Superconducting Wires}},
      Url = {http://dx.doi.org/10.1109/TMAG.2015.2480960},
      Volume = {52},
      Year = {2016}}
  • [DOI] G. Escamez, F. Sirois, V. Lahtinen, A. Stenvall, A. Badel, P. Tixador, B. Ramdane, G. Meunier, R. Perrin-Bit, and C. é. Bruzek, “3-D Numerical Modeling of AC Losses in Multifilamentary MgB2 Wires,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 3, p. 4701907, 2016.
    [Bibtex]
    @article{Escamez:TAS16,
      Author = {G. Escamez and F. Sirois and V. Lahtinen and A. Stenvall and A. Badel and P. Tixador and B. Ramdane and G. Meunier and R. Perrin-Bit and C. {\'E} Bruzek},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2533024},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {3},
      Pages = {4701907},
      Title = {{3-D Numerical Modeling of AC Losses in Multifilamentary MgB2 Wires}},
      Url = {http://dx.doi.org/10.1109/TASC.2016.2533024},
      Volume = {26},
      Year = {2016}}
  • [DOI] S. Farinon, G. Iannone, P. Fabbricatore, and U. Gambardella, “Numerical Modeling of Critical-State Magnetization in Type-II Superconducting Cylinders under Parallel and Transverse Magnetic Field,” Cryogenics, 2016.
    [Bibtex]
    @article{Farinon:Cryo16,
      Author = {S. Farinon and G. Iannone and P. Fabbricatore and U. Gambardella},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1016/j.cryogenics.2016.11.001},
      Journal = {Cryogenics},
      Title = {{Numerical Modeling of Critical-State Magnetization in Type-II Superconducting Cylinders under Parallel and Transverse Magnetic Field}},
      Url = {http://dx.doi.org/10.1016/j.cryogenics.2016.11.001},
      Year = {2016}}
  • [DOI] L. Gozzelino, R. Gerbaldo, G. Ghigo, F. Laviano, and M. Truccato, “Comparison of the Shielding Properties of Superconducting and Superconducting/Ferromagnetic Bi- and Multi-layer Systems,” Journal of Superconductivity and Novel Magnetism, pp. 1-8, 2016.
    [Bibtex]
    @article{Gozzelino_JSNM16,
      Abstract = {This paper compares the shielding properties of superconducting (SC) and superimposed superconducting/ferromagnetic (SC/FM) systems, consisting of cylindrical cups with an aspect ratio of height/radius close to unity. Both bilayer structures, with the SC cup placed inside the FM one, and multilayer structures, made up of two SC and two FM alternating cups, have been considered. Induction magnetic field values have been calculated by means of a finite element model based on the vector potential formulation, simultaneously taking into account the non-linear properties of both the SC and FM materials. The analysis highlights that at low applied fields, the presence of a height difference between the edges of the SC/FM cups, as well as a suitable choice of the lateral gap between the cups, is a key factor in obtaining hybrid structures with a shielding potential comparable to, or even higher than, that of the single SC cup. In contrast, at high applied fields, all the hybrid arrangements investigated always provide much greater shielding factors than the SC cup alone. The computation results show that at both low and high applied fields, the multilayer solutions are the hybrid shields with the highest efficiency.},
      Author = {L. Gozzelino and R. Gerbaldo and G. Ghigo and F. Laviano and M. Truccato},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1007/s10948-016-3659-z},
      Journal = {Journal of Superconductivity and Novel Magnetism},
      Pages = {1-8},
      Title = {{Comparison of the Shielding Properties of Superconducting and Superconducting/Ferromagnetic Bi- and Multi-layer Systems}},
      Url = {http://dx.doi.org/10.1007/s10948-016-3659-z},
      Year = {2016}}
  • [DOI] F. Grilli, V. M. ciak, A.Kario, and V. Zermeño, “HTS Roebel Cables: Self-Field Critical Current and AC Losses Under Simultaneous Application of Transport Current and Magnetic Field,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 4, p. 4803005, 2016.
    [Bibtex]
    @article{Grilli:TAS16b,
      Author = {F. Grilli and M. {Vojen{\v c}iak} and A.Kario and V. Zerme{\~n}o},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2536652},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {4},
      Pages = {4803005},
      Title = {{HTS Roebel Cables: Self-Field Critical Current and AC Losses Under Simultaneous Application of Transport Current and Magnetic Field}},
      Url = {http://dx.doi.org/10.1109/TASC.2016.2536652},
      Volume = {26},
      Year = {2016}}
  • [DOI] F. Grilli and Z. Xu, “Modeling AC ripple currents in HTS coated conductors by integral equations,” Cryogenics, vol. 80, iss. 400-404, 2016.
    [Bibtex]
    @article{Grilli:Cryo16,
      Author = {F. Grilli and Z. Xu},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1016/j.cryogenics.2016.04.013},
      Journal = {Cryogenics},
      Number = {400-404},
      Title = {{Modeling AC ripple currents in HTS coated conductors by integral equations}},
      Url = {http://dx.doi.org/10.1016/j.cryogenics.2016.04.013},
      Volume = {80},
      Year = {2016}}
  • [DOI] F. Grilli, “Numerical Modeling of HTS Applications,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 3, p. 500408, 2016.
    [Bibtex]
    @article{Grilli:TAS16a,
      Author = {F. Grilli},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2520083},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {3},
      Pages = {0500408},
      Title = {{Numerical Modeling of HTS Applications}},
      Url = {https://doi.org/10.1109/TASC.2016.2520083},
      Volume = {26},
      Year = {2016}}
  • [DOI] F. Grilli, V. M. R. Zermeño, and A. Kario, “Designing HTS Roebel cables for low-field applications with open-source code,” Physica C, vol. 530, pp. 120-122, 2016.
    [Bibtex]
    @article{Grilli:PhysC16,
      Author = {F. Grilli and V. M. R. Zerme{\~n}o and A. Kario},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1016/j.physc.2016.02.009},
      Journal = {Physica C},
      Pages = {120-122},
      Title = {{Designing HTS Roebel cables for low-field applications with open-source code}},
      Url = {http://dx.doi.org/10.1016/j.physc.2016.02.009},
      Volume = {530},
      Year = {2016}}
  • [DOI] J. Leclerc, M. L. Hell, C. Lorin, and P. J. Masson, “Artificial neural networks for AC losses prediction in superconducting round filaments,” Superconductor Science and Technology, vol. 29, iss. 6, p. 65008, 2016.
    [Bibtex]
    @article{Leclerc:SST16,
      Abstract = {An extensive and fast method to estimate superconducting AC losses within a superconducting round filament carrying an AC current and subjected to an elliptical magnetic field (both rotating and oscillating) is presented. Elliptical fields are present in rotating machine stators and being able to accurately predict AC losses in fully superconducting machines is paramount to generating realistic machine designs. The proposed method relies on an analytical scaling law (ASL) combined with two artificial neural network (ANN) estimators taking 9 input parameters representing the superconductor, external field and transport current characteristics. The ANNs are trained with data generated by finite element (FE) computations with a commercial software (FlexPDE) based on the widely accepted H-formulation. After completion, the model is validated through comparison with additional randomly chosen data points and compared for simple field configurations to other predictive models. The loss estimation discrepancy is about 3% on average compared to the FEA analysis. The main advantages of the model compared to FE simulations is the fast computation time (few milliseconds) which allows it to be used in iterated design processes of fully superconducting machines. In addition, the proposed model provides a higher level of fidelity than the scaling laws existing in literature usually only considering pure AC field.},
      Author = {J. Leclerc and L. Makong Hell and C. Lorin and P. J. Masson},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1088/0953-2048/29/6/065008},
      Journal = {Superconductor Science and Technology},
      Number = {6},
      Pages = {065008},
      Title = {{Artificial neural networks for AC losses prediction in superconducting round filaments}},
      Url = {http://dx.doi.org/10.1088/0953-2048/29/6/065008},
      Volume = {29},
      Year = {2016}}
  • [DOI] F. Liang, W. Yuan, M. Zhang, Z. Zhang, J. Li, S. Venuturumilli, and J. Patel, “AC loss modelling and experiment of two types of low-inductance solenoidal coils,” Superconductor Science and Technology, vol. 29, iss. 11, p. 115006, 2016.
    [Bibtex]
    @article{Liang:SST16,
      Abstract = {Low-inductance solenoidal coils, which usually refer to the nonintersecting type and the braid type, have already been employed to build superconducting fault current limiters because of their fast recovery and low inductance characteristics. However, despite their usage there is still no systematical simulation work concerning the AC loss characteristics of the coils built with 2G high temperature superconducting tapes perhaps because of their complicated structure. In this paper, a new method is proposed to simulate both types of coils with 2D axisymmetric models solved by H formulation. Following the simulation work, AC losses of both types of low inductance solenoidal coils are compared numerically and experimentally, which verify that the model works well in simulating non-inductive coils. Finally, simulation works show that pitch has significant impact to AC loss of both types of coils and the inter-layer separation has different impact to the AC loss of braid type of coil in case of different applied currents. The model provides an effective tool for the design optimisation of SFCLs built with non-inductive solenoidal coils.},
      Author = {F. Liang and W. Yuan and M. Zhang and Z. Zhang and J. Li and S. Venuturumilli and J. Patel},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1088/0953-2048/29/11/115006},
      Journal = {Superconductor Science and Technology},
      Number = {11},
      Pages = {115006},
      Title = {{AC loss modelling and experiment of two types of low-inductance solenoidal coils}},
      Url = {http://dx.doi.org/10.1088/0953-2048/29/11/115006},
      Volume = {29},
      Year = {2016}}
  • [DOI] L. Makong, A. Kameni, P. Masson, J. Lambrechts, and F. Bouillault, “3-D Modeling of Heterogeneous and Anisotropic Superconducting Media,” IEEE Transactions on Magnetics, vol. 52, iss. 3, 2016.
    [Bibtex]
    @article{Makong:TMAG16,
      Author = {L. Makong and A. Kameni and P. Masson and J. Lambrechts and F. Bouillault},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TMAG.2015.2497580},
      Journal = {IEEE Transactions on Magnetics},
      Number = {3},
      Title = {{3-D Modeling of Heterogeneous and Anisotropic Superconducting Media}},
      Url = {http://doi.org/10.1109/TMAG.2015.2497580},
      Volume = {52},
      Year = {2016}}
  • [DOI] A. Morandi, M. B. Gholizad, F. Grilli, F. Sirois, and V. M. R. Zermeño, “Design and Comparison of a 1 MW / 5s HTS SMES with Toroidal and Solenoidal Geometry,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 4, p. 5700606, 2016.
    [Bibtex]
    @article{Morandi:TAS16,
      Author = {A. Morandi and M. B. Gholizad and F. Grilli and F. Sirois and V. M. R. Zerme{\~n}o},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2535271},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {4},
      Pages = {5700606},
      Title = {{Design and Comparison of a 1 MW / 5s HTS SMES with Toroidal and Solenoidal Geometry}},
      Url = {http://dx.doi.org/10.1109/TASC.2016.2535271},
      Volume = {26},
      Year = {2016}}
  • [DOI] E. Pardo, M. Kapolka, K. J. c, J. vSouc, F. Grilli, and N. R. A. Piqué, “Three-Dimensional Modeling and Measurement of Coupling AC Loss in Soldered Tapes and Striated Coated Conductors,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 3, p. 4700607, 2016.
    [Bibtex]
    @article{Pardo:TAS16,
      Author = {E. Pardo and M. Kapolka and J. Kov{\'a}{\v c} and J. \v{S}ouc and F. Grilli and R. Nast A. Piqu{\'e}},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {doi: 10.1109/TASC.2016.2523758},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {3},
      Pages = {4700607},
      Title = {{Three-Dimensional Modeling and Measurement of Coupling AC Loss in Soldered Tapes and Striated Coated Conductors}},
      Url = {http://dx.doi.org/10.1109/TASC.2016.2523758},
      Volume = {26},
      Year = {2016}}
  • [DOI] E. Pardo, “Modeling of screening currents in coated conductor magnets containing up to 40000 turns,” Superconductor Science and Technology, vol. 29, iss. 8, p. 85004, 2016.
    [Bibtex]
    @article{Pardo:SST16,
      Abstract = {Screening currents caused by varying magnetic fields degrade the homogeneity and stability of the magnetic fields created by RE BCO coated conductor coils. They are responsible for the AC loss; which is also important for other power applications containing windings, such as transformers, motors and generators. Since real magnets contain coils exceeding 10000 turns, accurate modeling tools for this number of turns or above are necessary for magnet design. This article presents a fast numerical method to model coils with no loss of accuracy. We model a 10400-turn coil for its real number of turns and coils of up to 40000 turns with continuous approximation, which introduces negligible errors. The screening currents, the screening current induced field (SCIF) and the AC loss is analyzed in detail. The SCIF is at a maximum at the remnant state with a considerably large value. The instantaneous AC loss for an anisotropic magnetic-field dependent J c is qualitatively different than for a constant J c , although the loss per cycle is similar. Saturation of the magnetization currents at the end pancakes causes the maximum AC loss at the first ramp to increase with J c . The presented modeling tool can accurately calculate the SCIF and AC loss in practical computing times for coils with any number of turns used in real windings, enabling parameter optimization.},
      Author = {E Pardo},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1088/0953-2048/29/8/085004},
      Journal = {Superconductor Science and Technology},
      Number = {8},
      Pages = {085004},
      Title = {{Modeling of screening currents in coated conductor magnets containing up to 40000 turns}},
      Url = {http://dx.doi.org/10.1088/0953-2048/29/8/085004},
      Volume = {29},
      Year = {2016}}
  • [DOI] L. Quéval, V. M. R. Zermeño, and F. Grilli, “Numerical models for ac loss calculation in large-scale applications of HTS coated conductors,” Superconductor Science and Technology, vol. 29, iss. 2, p. 24007, 2016.
    [Bibtex]
    @article{Queval:SST16,
      Abstract = {Numerical models are powerful tools to predict the electromagnetic behavior of superconductors. In recent years, a variety of models have been successfully developed to simulate high-temperature-superconducting (HTS) coated conductor tapes. While the models work well for the simulation of individual tapes or relatively small assemblies, their direct applicability to devices involving hundreds or thousands of tapes, e.g., coils used in electrical machines, is questionable. Indeed, the simulation time and memory requirement can quickly become prohibitive. In this paper, we develop and compare two different models for simulating realistic HTS devices composed of a large number of tapes: (1) the homogenized model simulates the coil using an equivalent anisotropic homogeneous bulk with specifically developed current constraints to account for the fact that each turn carries the same current; (2) the multi-scale model parallelizes and reduces the computational problem by simulating only several individual tapes at significant positions of the coil's cross-section using appropriate boundary conditions to account for the field generated by the neighboring turns. Both methods are used to simulate a coil made of 2000 tapes, and compared against the widely used H-formulation finite-element model that includes all the tapes. Both approaches allow faster simulations of large number of HTS tapes by 1--3 orders of magnitudes, while maintaining good accuracy of the results. Both models can therefore be used to design and optimize large-scale HTS devices. This study provides key advancement with respect to previous versions of both models. The homogenized model is extended from simple stacks to large arrays of tapes. For the multi-scale model, the importance of the choice of the current distribution used to generate the background field is underlined; the error in ac loss estimation resulting from the most obvious choice of starting from a uniform current distribution is revealed.},
      Author = {L. Qu{\'e}val and V. M. R. Zerme{\~n}o and F. Grilli},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1088/0953-2048/29/2/024007},
      Journal = {Superconductor Science and Technology},
      Number = {2},
      Pages = {024007},
      Title = {{Numerical models for ac loss calculation in large-scale applications of HTS coated conductors}},
      Url = {http://dx.doi.org/10.1088/0953-2048/29/2/024007},
      Volume = {29},
      Year = {2016}}
  • [DOI] J. Sheng, D. Hu, K. Ryu, H. S. Yang, Z. Y. Li, and Z. Hong, “Numerical Study on Overcurrent Process of High-Temperature Superconducting Coated Conductors,” Journal of Superconductivity and Novel Magnetism, pp. 1-8, 2016.
    [Bibtex]
    @article{Sheng:JSNM16,
      Abstract = {Overcurrent performance of high-temperature superconducting (HTS) coated conductor (CC) is one of the most crucial parameters for industrial applications, especially in superconducting fault current limiters (SFCLs). Thus, numerical study of overcurrent process becomes desirable in design of these superconducting devices. In this paper, a field-circuit combined model is introduced to study the overcurrent process of HTS CCs. This model is built by both MATLAB and COMSOL. Circuit parameters, electromagnetic, and temperature distributions are individually calculated by different software. Temperature (T), magnetic intensity (B), and generated heat (Q) are used as real-time intermediate exchanging variables. Accuracy of this model is verified by short-fault experiments on straight HTS CC. Further applications, such as reclosing process and superconducting coils are both performed. Results obtained in this paper prove the validity of this model; this model can be helpful in future design of superconducting devices.},
      Author = {J. Sheng and D. Hu and K. Ryu and H. S. Yang and Z. Y. Li and Z. Hong},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1007/s10948-016-3754-1},
      Journal = {Journal of Superconductivity and Novel Magnetism},
      Pages = {1--8},
      Title = {{Numerical Study on Overcurrent Process of High-Temperature Superconducting Coated Conductors}},
      Url = {http://dx.doi.org/10.1007/s10948-016-3754-1},
      Year = {2016}}
  • [DOI] S. Song, W. S. Lee, Y. G. Park, S. Nam, H. Jeon, G. Baek, M. C. Ahn, J. Lee, Y. Choi, and T. K. Ko, “Analysis of the Notch Effect on Flux Diverters for High-Temperature Superconducting Magnets,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 4, p. 4601604, 2016.
    [Bibtex]
    @article{Song:TAS16,
      Author = {S. Song and W. S. Lee and Y. G. Park and S. Nam and H. Jeon and G. Baek and M. C. Ahn and J. Lee and Y. Choi and T. K. Ko},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2541082},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {4},
      Pages = {4601604},
      Title = {Analysis of the Notch Effect on Flux Diverters for High-Temperature Superconducting Magnets},
      Url = {http://doi.org/10.1109/TASC.2016.2541082},
      Volume = {26},
      Year = {2016}}
  • [DOI] W. Ta and Y. Gao, “Electromagnetic–Mechanical Coupling Analysis of Nb3Sn Superconducting Strand,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 4, p. 6001205, 2016.
    [Bibtex]
    @article{Ta:TAS16,
      Author = {W. Ta and Y. Gao},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2536200},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {4},
      Pages = {6001205},
      Title = {{Electromagnetic--Mechanical Coupling Analysis of Nb3Sn Superconducting Strand}},
      Url = {https://doi.org/10.1109/TASC.2016.2536200},
      Volume = {26},
      Year = {2016}}
  • [DOI] C. R. Vargas-Llanos, V. M. R. Zermeño, S. Sanz, F. Trillaud, and F. Grilli, “Estimation of hysteretic losses in $\rm MgB_2$ tapes under the operating conditions of a generator,” Superconductor Science and Technology, vol. 29, iss. 3, p. 34008, 2016.
    [Bibtex]
    @article{VargasLlanos:SST16,
      Author = {C. R. Vargas-Llanos and V. M. R. Zerme{\~n}o and S. Sanz and F. Trillaud and F. Grilli},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1088/0953-2048/29/3/034008},
      Journal = {Superconductor Science and Technology},
      Number = {3},
      Pages = {034008},
      Title = {{Estimation of hysteretic losses in $\rm MgB_2$ tapes under the operating conditions of a generator}},
      Url = {http://dx.doi.org/10.1088/0953-2048/29/3/034008},
      Volume = {29},
      Year = {2016}}
  • [DOI] C. Q. Ye, G. T. Ma, K. Liu, and J. S. Wang, “Intelligent Optimization of an HTS Maglev System With Translational Symmetry,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 4, p. 3600305, 2016.
    [Bibtex]
    @article{Ye:TAS16,
      Author = {C. Q. Ye and G. T. Ma and K. Liu and J. S. Wang},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2519280},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {4},
      Pages = {3600305},
      Title = {{Intelligent Optimization of an HTS Maglev System With Translational Symmetry}},
      Url = {http://dx.doi.org/10.1109/TASC.2016.2519280},
      Volume = {26},
      Year = {2016}}
  • [DOI] V. M. R. Zermeño, S. Quaiyum, and F. Grilli, “Open-Source Codes for Computing the Critical Current of Superconducting Devices,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 3, p. 4901607, 2016.
    [Bibtex]
    @article{Zermeno:TAS16,
      Author = {V. M. R. Zerme{\~n}o and S. Quaiyum and F. Grilli},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2521171},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {3},
      Pages = {4901607},
      Title = {{Open-Source Codes for Computing the Critical Current of Superconducting Devices}},
      Url = {http://dx.doi.org/10.1109/TASC.2016.2521171},
      Volume = {26},
      Year = {2016}}
  • [DOI] S. Zou, V. M. R. Zermeño, and F. Grilli, “Influence of Parameters on the Simulation of HTS Bulks Magnetized by Pulsed Field Magnetization,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 4, p. 4702405, 2016.
    [Bibtex]
    @article{Zou:TAS16b,
      Author = {S. Zou and V. M. R. Zerme{\~n}o and F. Grilli},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2535379},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {4},
      Pages = {4702405},
      Title = {{Influence of Parameters on the Simulation of HTS Bulks Magnetized by Pulsed Field Magnetization}},
      Url = {http://dx.doi.org/10.1109/TASC.2016.2535379},
      Volume = {26},
      Year = {2016}}
  • [DOI] S. Zou, V. M. R. Zermeño, and F. Grilli, “Simulation of Stacks of High Temperature Superconducting Coated Conductors Magnetized by Pulsed Field Magnetization Using Controlled Magnetic Density Distribution Coils,” IEEE Transactions on Applied Superconductivity, vol. 26, iss. 3, p. 8200705, 2016.
    [Bibtex]
    @article{Zou:TAS16a,
      Author = {S. Zou and V. M. R. Zerme{\~n}o and F. Grilli},
      Date-Added = {2019-10-15 14:46:19 +0200},
      Date-Modified = {2019-10-15 14:46:19 +0200},
      Doi = {10.1109/TASC.2016.2520210},
      Journal = {IEEE Transactions on Applied Superconductivity},
      Number = {3},
      Pages = {8200705},
      Title = {{Simulation of Stacks of High Temperature Superconducting Coated Conductors Magnetized by Pulsed Field Magnetization Using Controlled Magnetic Density Distribution Coils}},
      Url = {http://dx.doi.org/10.1109/TASC.2016.2520210},
      Volume = {26},
      Year = {2016}}

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