Ing. Kapolka Milan

Ghabeli, A., Pardo, E., and Kapolka, M.: 3D modeling of a superconducting dynamo-type flux pump, Sci Rep. 11 (2021) 10296.

1. Wen, Z.Z.: Supercond. Sci Technol. 34 (2021) 125019. 2. Fawaz, S.: Supercond. Sci Technol. 34 (2021) 124001. 3. Sokolovsky, V.: Supercond. Sci Technol. 35 (2022) 024002.

Kapolka, M., Pardo, E., Grilli, F., Baskys, A., Climente-Alarcon, V., Dadhich, A., and  Glowacki, B.A.: Cross-field demagnetization of stacks of tapes: 3D modeling and measurements, Supercond. Sci Technol. 33 (2020) 044019.

1. Zhang, H.Y.: Supercond. Sci Technol. 34 (2021) 045018. 2. Hu, J.T.: IEEE Trans. Applied Supercond. 31 (2021) 8200106. 3. Suyama, M.: J. Phys. Conf. Ser. 1975 (2021) 012014.

Grilli, F., Benkel, T., Hänisch, J., Lao, M., Reis, T., Berberich, E., Wolfstädter, S., Schneider, C., Miller, P., Palmer, C., Glowacki, B., Climente-Alarcon, V., Smara, A., Tomkow, L., Teigelkötter, J., Stock, A., Büdel, J., Jeunesse, L., Staempflin, M., Delautre, G., Zimmermann, B., van der Woude, R., Perez, A., Samoilenkov, S., Molodyk, A., Pardo, E., Kapolka, M., Li, S., and Dadhich, A.: Superconducting  motors  for  aircraft  propulsion:  the  advanced  superconducting motor experimental demonstrator project, J. Phys.: Conf. Ser. 1590 (2020)  012051.

1. Seitz, A.: Aerospace 8 (2021) 16. 2. Zanegin, S.: Applied Sci 11 (2021) 2741. 3. Zhang, H.Y.: Supercond. Sci Technol. 34 (2021) 045018. 4. Dorget, R.: Materials 14 (2021) 2847. 5. Sasa, H.: IEEE Trans. Applied Supercond. 31 (2021) 5200706. 6. Arndt, T.: Supercond. Sci Technol. 34 (2021) 095006. 7. Sheng, J.: IEEE Trans. Applied Supercond. 31 (2021) 5500605.

Dadhich, A., Pardo, E., and Kapolka, M.: Time constant of the transverse-field demagnetization of superconducting stacks of tapes, Supercond. Sci Technol. 33 (2020) 065003.

1. Tomkow, L.: IEEE Trans. Applied Supercond. 30 (2020) Iss.‏ 8. 2. Harca, I. M.: Supercond. Sci Technol. 33 (2020) 115004. 3. Tomkow, L.: Cryogenics 112 (2020) 103206. 4. Zhong, Z.Y.: Supercond. Sci Technol. 34 (2021) 08LT01. 5. Zhang, H.Y.: Supercond. Sci Technol. 34 (2021) 045018. 6. Suyama, M.: J. Phys. Conf. Ser. 1975 (2021) 012014.

Kapolka, M. and Pardo, E.: 3D modelling of macroscopic force-free effects in superconducting thin films and rectangular prisms, Supercond. Sci Technol. 32 (2019) 054001.

1. Solovyov, M.: Supercond. Sci Technol. 32 (2019) 115001. 2. Ainslie, M.: Numer. Modell. Bulk Supercond. Magnet. IoP Publ. 2020. ISBN: 978-0-7503-1333-9. 3. Shen, B.: IEEE Access 8 (2020) 100403. 4. Lai, L.: Supercond. Sci Technol. 34 (2021) 015003. 5. Zhang, H.Y.: Energies 14 (2021) 2234.

Kapolka, M., Srpcic, J., Zhou, D., Ainslie, M.D., Pardo, E., and Dennis, A.R.: Demagnetization of cubic Gd-Ba-Cu-O bulk superconductor by crossed-fields: measurements and three-dimensional modeling, IEEE Trans. Applied Supercond. 28 (2018) 6801405.

1. Prigozhin, L.: Supercond. Sci Technol. 31 (2018) 055018. 2. Prigozhin, L.: J. Applied Phys. 123 (2018) 233901. 3. Prigozhin, L.: Supercond. Sci Technol. 31 (2018) 125001. 4. Olm, M.: Computer Phys. Comm. 237 (2019) 154.| 5. Barba-Ortega, J.: Physica C 558 (2019) 1. 6. Morandi, A.: IEEE Trans. Magnet. 56 (2020) 7401114. 7. Arsenault, A.: IEEE Trans. Applied Supercond. 31 (2021) 6800111.

Kapolka, M., Zermeno, V.M.R., Zou, S., Morande, A., Ribani, P.L., Pardo, E., and Grilli, F.: Three-dimensional modeling of the magnetization of superconducting rectangular-based bulks and tape stacks, IEEE Trans. Applied Supercond. 28 (2018) 8201206.

1. Prigozhin, L.: Supercond. Sci Technol. 31 (2018) 055018. 2. Prigozhin, L.: J. Applied Phys. 123 (2018) 233901. 3. Barba-Ortega, J.: Physica C 558 (2019) 1. 4. Hao, L.: IEEE Trans. Applied Supercond. 29 (2019) 5202405. 5. Solovyov, M.: Supercond. Sci Technol. 32 (2019) 115001. 6. Ainslie, M.: Numer. Modell. Bulk Supercond. Magnet. IoP Publ. 2020. ISBN: 978-0-7503-1333-9. 7. Bortot, L.: IEEE Trans. Applied Supercond. 30 (2020) 4900911. 8. Xu, M.: IEEE Trans. Applied Supercond. 31 (2021) 6400703. 9. Sumption, M.D.: Supercond. Sci Technol. 35 (2022) 025006.

Pardo, E. and Kapolka, M.: 3D magnetization currents, magnetization loop, and saturation field in superconducting rectangular prisms, Supercond. Sci Technol. 30 (2017) 064007.

1. Morandi, A.: Supercond. Sci Technol. 31 (2018) 080201. 2. Prigozhin, L.: Supercond. Sci Technol. 31 (2018) 055018. 3. Prigozhin, L.: J. Applied Phys. 123 (2018) 233901. 4. Olm, M.: Computer Phys. Comm. 237 (2019) 154. 5. Wera, L.: IEEE Trans. Applied Supercond. 29 (2019) 6801109. 6. Barba-Ortega, J.: Physica C 558 (2019) 1. 7. Dulare, J.: IEEE Trans. Applied Supercond. 30 (2020) 8200113. 8. Houbart, M.: Supercond. Sci Technol. 33 (2020) 064003. 9. Wang, Y.: High Voltage 5 (2020)‏ SI218. 10. Zhang, K.: Supercond. Sci Technol. 34 (2021) 094002.

Pardo, E. and Kapolka, M.: 3D computation of non-linear eddy currents: Variational method and superconducting cubic bulk, J. Comput. Phys. 344 (2017) 339–363.

1. Prigozhin, L.: Supercond. Sci Technol. 31 (2018) 055018. 2. Prigozhin, L.: Supercond. Sci Technol. 31 (2018) 125001. 3. Prigozhin, L.: J. Applied Phys. 123 (2018) 233901. 4. Olm, M.: Computer Phys. Comm. 237 (2019) 154. 5. Barba-Ortega, J.: Physica C 558 (2019) 1. 6. Blandine, R.: Supercond. Sci Technol. 32 (2019) 044008. 7. Mu Y.-P.: Optoelectron. Lett. 15 (2019) 217. 8. Ainslie, M.: Numer. Modell. Bulk Supercond. Magnet. IoP Publ. 2020. ISBN: 978-0-7503-1333-9. 9. Baek, G.: IEEE Trans. Applied Supercond. 30 (2020) Iss.‏ 4. 10. Zhang, K.: Supercond. Sci Technol. 33 (2020) 114007. #     11. Soomro, W.A.: IEEE Inter. Conf. Applied Supercond. Electromagn. Dev. – ASEMD 2020, no. 9276278. 12. Xu, A.: IEEE Trans. Applied Supercond. 31 (2021) Iss.‏ 1. 13. Zhang, K.: IEEE Trans. Applied Supercond. 31 (2021) 1. 14. Qian, K.Z.: IEEE Trans. Applied Supercond. 31 (2021) 4901308. 15. Zhang, K.: Supercond. Sci Technol. 34 (2021) 094002. 16. Arsenault, A.: IEEE Trans. Applied Supercond. 31 (2021) 6800609. 17. Wen, Z.Z.: Supercond. Sci Technol. 34 (2021) 125019.

Pardo, E., Kapolka, M., Kováč, J., Šouc, J., Grilli, F., and Pique, A.: Three-dimensional modeling and measurement of coupling AC loss in soldered tapes and striated coated conductors, (Invited paper) IEEE Trans. Applied Supercond. 26 (2016) 4700607.

1. Amemiya, N.: Supercond. Sci Technol. 31 (2018) 025007. 2. Stenvall, A.: IEEE Trans. Applied Supercond. 29 (2019) 5901207. 3. Higashi, Y.: Supercond. Sci Technol. 32 (2019) 055010. 4. Yan, Y.: IEEE Trans. Applied Supercond. 30 (2020) Iss.‏ 4. 5. Sogabe, Y.: Supercond. Sci Technol. 33 (2020) 055008. 6. Sogabe, Y.: Supercond. Sci Technol. 34 (2021) 105009. 7. Sumption, M.D.: Supercond. Sci Technol. 35 (2022) 025006. 8. Luo, X.J.: IEEE Trans. Applied Supercond. 32 (2022) 6600609. 9. Hao, L.N.: IEEE Trans. Applied Supercond. 32 (2022) 5900505.

Pardo, E., Kapolka, M.,  and Šouc, J.: 3D and 2D electromagnetic modelling of superconductors: flux cutting effects in finite samples and coated conductor coils up to 10000 turns In: EUCAS 2015. Lyon 2015.

1. Grilli, F.: IEEE Trans. Applied Supercond. 26 (2016) 0500408. 2. Berrospe-Juarez, E.: Supercond. Sci Technol. 32 (2019) 065003.