Stabilizatsiya pretsessii namagnichennosti v SFS φ 0-perekhode v oblasti ferromagnitnogo rezonansa

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Abstract

Исследована динамика намагниченности LC-шунтированного джозефсоновского SFS φ 0 перехода в случае, когда частоты ферромагнитного и параллельного резонансов находятся в непосредственной близости друг к другу. Рассчитанные вольт-амперные характеристики и зависимости намагниченности ферромагнитного F-слоя от тока через SFS-переход коррелируют с соответствующими временными зависимостями намагниченности my (t) и напряжения V(t). Продемонстрирована уникальная возможность стабилизации прецессии намагниченности посредством LC-шунтирования в довольно широкой области токов через переход.

References

  1. A.V. Ustinov and V.K. Kaplunenko, “Rapid single- flux quantum logic using π-shifters”, J. Appl. Phys. 94, 5405 (2003).
  2. A.K. Feofanov, V.A. Oboznov, V.V. Bol’ginov, J. Lisenfeld, S. Poletto, V.V. Ryazanov, A.N. Rossolenko, M. Khabipov, D. Balashov, A.B. Zorin, P.N. Dmitriev, V.P. Koshelets, and A.V. Ustinov, “Implementation of superconductor/ferromagnet/superconductor π-shifters in superconducting digital and quantum circuits”, Nature Phys. 6, 593 (2010).
  3. J. Linder and J.W.A. Robinson, “Superconducting spintronics”, Nature Phys. 11, 307 (2015).
  4. I. I. Soloviev, V. I. Ruzhickiy, S.V. Bakurskiy, N.V. Klenov, M.Yu. Kupriyanov, A.A. Golubov, O.V. Skryabina, and V. S. Stolyarov, “Superconducting circuits without inductors based on bistable Josephson junctions”, Phys. Rev. Appl. 16, 014052 (2021).
  5. А.С. Мельников, С. В. Миронов, А.В. Самохвалов, А.И. Буздин, “Сверхпроводящая спинтроника: современное состояние и перспективы”, УФН 192, 1339 (2022)
  6. S. Mel’nikov, S.V. Mironov, A.V. Samokhvalov, and A. I. Buzdin, “Superconducting spintronics: state of the art and prospects”, Phys.-Uspekhi 65, 1248 (2022).
  7. N.O. Birge and N. Satchell, “Ferromagnetic materials for Josephson π junctions”, APL Mater. 12, 041105 (2024).
  8. A. I. Buzdin, “Direct coupling between magnetism and superconducting current in the Josephson junction”, Phys. Rev. Lett. 101, 107005 (2008).
  9. F. Konschelle and A. I. Buzdin, “Magnetic moment manipulation by a Josephson current”, Phys. Rev. Lett. 102(1), 017001 (2009).
  10. Yu.M. Shukrinov. “Anomalous Josephson effect”, Phys.-Uspekhi 65, 317 (2022).
  11. H. Sickinger, A. Lipman, M. Weides, R.G. Mints, H. Kohlstedt, D. Koelle, R. Kleiner, and E. Goldobin, “Experimental evidence of a φ Josephson junction”, Phys. Rev. Lett. 109 107002 (2012).
  12. D.B. Szombati, S. Nadj-Perge, D. Car, S.R. Plissard, E.P.A.M. Bakkers, and L.P. Kouwenhoven, “Josephson ϕ0-junction in nanowire quantum dots”, Nature Phys. 12(6), 568 (2016).
  13. A. Assouline, C. Feuillet-Palma, N. Bergeal, T. Zhang, A. Mottaghizadeh, A. Zimmers, E. Lhuillier, M. Eddrie, P. Atkinson, M. Aprili, and H. Aubin, “Spin-Orbit induced phase-shift in Bi2Se3 Josephson junctions”, Nat. Commun. 10(1), 126 (2019).
  14. E. Strambini, A. Iorio, O. Durante, R. Citro, C. Sanz-Fern`andez, C. Guarcello, I.V. Tokatly, A. Braggio, M. Rocci, N. Ligato, V. Zannier, L. Sorba, F. S. Bergeret, and F. Giazotto, “A Josephson phase battery”, Nat. Nanotechnol. 15, 656 (2020).
  15. W. Mayer, M.C. Dartiailh, J. Yuan, K. S. Wickramasinghe, E. Rossi, and J. Shabani, “Gate controlled anomalous phase shift in Al/InAs Josephson junctions”, Nat. Commun. 11, 212 (2020).
  16. G.A. Bobkov, I.V. Bobkova, and A.M. Bobkov, “Magnetic eigenmodes in chains of coupled ϕ0Josephson junctions with ferromagnetic weak links”, JETP Lett. 119(3), 251 (2024).
  17. Yu.M. Shukrinov , I.R. Rahmonov, K.V. Kulikov, and P. Seidel, “Effects of LC shunting on the Shapiro steps features of Josephson junction Europhys. Lett. 110(4), 47001 (2015).
  18. Yu.M. Shukrinov, I.R. Rahmonov, K.V. Kulikov, A.E. Botha, A. Plecenik, P. Seidel, and W. Nawrocki, “Modeling of LC-Shunted Intrinsic Josephson Junctions in High-Tc Superconductors”, Supercond. Sci. Tech. 30(2), 024006, (2017).
  19. Yu.M. Shukrinov, A. S. Abouhaswa, and A.E. Botha, “Double and triple resonance behaviour in large systems of LC-Shunted intrinsic Josephson junctions”, Phys. Lett. A 387, 127025 (2021).
  20. A.E. Botha, Yu.M. Shukrinov, and J. Tekic, “Chaos along the rc-branch of RLC-shunted intrinsic Josephson junctions”, Chaos Solit. Fractals 156, 111865 (2022).
  21. К.К. Лихарев, Введение в динамику джозефсоновских переходов (Наука, М., 1985) [in Russian]
  22. K.K. Likharev, Dynamics of Josephson junctions and circuits, (Gordon and Breach, N.Y., 1986).
  23. M. S. Shevchenko, A.A. Atepalikhin, F.V. Khan, L.V. Filippenko, A.M. Chekushkin, and V.P. Koshelets, “Shunted Josephson junctions and optimization of niobium integrated matching circuits”, IEEE Transact. Appl. Supercond. 32(4), 1100205 (2021).
  24. S.K. Tolpygo, V. Bolkhovsky, S. Zarr, T. J. Weir, A. Wynn, A. L. Day, L.M. Johnson, and M.A. Gouker, “Properties of unshunted and resistively shunted Nb/AlOx-Al/Nb Josephson junctions with critical current densities from 0.1 to 1 mA/μm2”, IEEE Transact. Appl. Supercond. 27 (4), 1100815 (2017).
  25. Yu.M. Shukrinov, E. Kovalenko, J. Tekic, K. Kulikov, and M. Nashaat, “Buzdin, Shapiro, and chimera steps in ϕ0 Josephson junctions”, Phys. Rev. B 109, 024511 (2024).
  26. M. Nashaat, E. Kovalenko, and Yu.M. Shukrinov, “Buzdin, Shapiro, and chimera steps in ϕ0 Josephson junctions. II. Bifurcation, switching, and hysteresis”, Phys. Rev. B, 110, 024510 (2024).
  27. M. Nashaat and Yu.M. Shukrinov, “Originality of resonance and locking phenomena in junction”, Condmat arXiv:2508.13994.
  28. I.R. Rahmonov, Yu.M. Shukrinov, O.A. Kibardina, and S.A. Abdelmoneim, “Resonant control of magnetization in a shunted ϕ0 junction with LC circuit”, Appl. Phys. Lett. 126, 232603 (2025).
  29. Yu.M. Shukrinov, F. Mahfouzi, and N. F. Pedersen, “Investigation of the breakpoint region in stacks with a finite number of intrinsic Josephson junctions”, Phys. Rev. B 75, 104508 (2007).
  30. W. Buckel and R. Kleiner, Superconductivity: Fundamentals and Application (Wiley-VCH, Verlag GmbH and Co. KGaA, Weinheim, 2004).
  31. Yu.M. Shukrinov, I.R. Rahmonov, and K. Sengupta, “Ferromagnetic resonance and magnetic precessions in ϕ0 junctions”, Phys. Rev. B 99, 224513 (2019).
  32. Yu.M. Shukrinov, I.R. Rahmonov and K.V. Kulikov, “Double resonance in the system of coupled Josephson junctions”, JETP Lett. 96, 657 (2012).
  33. Yu.M. Shukrinov, I.R. Rahmonov, and G. Filatrella, “Dependence of the maximal superconducting current on the resonance frequency in a shunted Josephson junction”, JETP 125, 781 (2017).
  34. T. I. Larkin, V.V. Bol’ginov, V. S. Stolyarov, V.V. Ryazanov, I.V. Vernik, S.K. Tolpygo, and O.A. Mukhanov, “Ferromagnetic Josephson switching device with high characteristic voltage”, Appl. Phys. Lett. 100, 222601 (2012).
  35. T. E. Golikova, F. Hubler, D. Beckmann, I.E. Batov, T.Yu. Karminskaya, M.Yu. Kupriyanov, A.A. Golubov, and V.V. Ryazanov, “Double proximity effect in hybrid planar superconductor- (normal metal/ferromagnet)-superconductor structures”, Phys. Rev. B 86, 064416 (2012).
  36. A.E. Schegolev, M.V. Bastrakova, M.A. Sergeev, A.A. Maksimovskaya, N.V. Klenov, and I. I. Soloviev, “Contemporary implementations of spiking bio-inspired neural networks”, Mesoscience & Nanotechnology 1, 0101005 (2024).
  37. A.E. Schegolev, N.V. Klenov, S.V. Bakurskiy, I. I. Soloviev, M.Y. Kupriyanov, M.V. Tereshonok, and A. S. Sidorenko, “Tunable superconducting neurons for networks based on radial basis functions”, Beilstein J. Nanotechnol. 13, 444 (2022).
  38. A.E. Schegolev, N.V. Klenov, I. I. Soloviev, A. L. Gudkov, and M.V. Tereshonok, “Superconducting neural networks: from an idea to fundamentals and, further, to application”, Nanobiotechnology Reports 16, 811 (2021).
  39. I. I. Soloviev, A.E. Schegolev, N.V. Klenov, S.V. Bakurskiy, M.Y. Kupriyanov, M.V. Tereshonok, A.V. Shadrin, V. S. Stolyarov, and A.A. Golubov, “Adiabatic superconducting artificial neural network: Basic cells”, J. Appl. Phys. 124, 152113 (2018).

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