PACS numbers

73.50.Jt Galvanomagnetic and other magnetotransport effects (including thermomagnetic effects) 85.75.−d Magnetoelectronics; spintronics: devices exploiting spin polarized transport or integrated magnetic fields 85.80.Lp Magnetothermal devices
  1. Yu.M. Kuznetsov, M.V. Dorokhin et alGalvanomagnetic and thermomagnetic phenomena in thin metal CoPt films66 312–319 (2023)
    73.50.Jt, 85.75.−d, 85.80.Lp (all)
  2. Yu.M. Shukrinov “Anomalous Josephson effect65 317–354 (2022)
    74.50.+r, 85.25.Cp, 85.75.−d (all)
  3. V.M. Pudalov “Measurements of the magnetic properties of conduction electrons64 3–27 (2021)
    07.55.Jg, 75.70.−i, 85.75.−d (all)
  4. S.A. Nikitov, A.R. Safin et alDielectric magnonics: from gigahertz to terahertz63 945–974 (2020)
    85.70.−w, 85.75.−d (all)
  5. P.G. Baranov, A.M. Kalashnikova et alSpintronics of semiconductor, metallic, dielectric, and hybrid structures (100th anniversary of the Ioffe Institute)62 795–822 (2019)
    75.30.Kz, 75.50.Bb, 75.50.Gg, 75.76.+j, 75.78.Jp, 76.70.Hb, 78.30.Fs, 78.55.Et, 85.75.−d (all)
  6. D.A. Tatarskiy, A.V. Petrenko et alFeatures of the motion of spin 1/2 particles in a noncoplanar magnetic field59 583–587 (2016)
    03.65.Nk, 28.20.−v, 85.75.−d (all)
  7. V.A. Soltamov, P.G. Baranov “Radio spectroscopy of the optically aligned spin states of color centers in silicon carbide59 605–610 (2016)
    76.30.−v, 78.47.−p, 85.75.−d (all)
  8. A.P. Pyatakov, A.S. Sergeev et alMicromagnetism and topologic defects in magnetoelectric media58 981–992 (2015)
    75.85.+t, 85.70.−w, 85.75.−d (all)
  9. S.A. Nikitov, D.V. Kalyabin et alMagnonics: a new research area in spintronics and spin wave electronics58 1002–1028 (2015)
    75.30.Ds, 85.70.−w, 85.75.−d (all)
  10. Spintronics and nanomagnetism (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 25 April 2012)55 1255–1267 (2012)
    01.10.Fv, 61.72.−y, 62.20.−x, 62.30.+d, 75.47.−m, 75.75.−c, 85.75.−d (all)
  11. A.A. Fraerman “Magnetic states and transport properties of ferromagnetic nanostructures55 1255–1260 (2012)
    75.47.−m, 75.75.−c, 85.75.−d (all)
  12. A.P. Pyatakov, A.K. Zvezdin “Magnetoelectric and multiferroic media55 557–581 (2012)
    75.85.+t, 85.70.−w, 85.75.−d (all)
  13. N.V. Volkov “Spintronics: manganite-based magnetic tunnel structures55 250–269 (2012)
    72.25.−b, 75.76.+j, 85.75.−d (all)
  14. Yu.G. Kusrayev “Spin phenomena in semiconductors: physics and applications53 725–738 (2010)
    75.47.−m, 75.76.+j, 85.75.−d (all)
  15. S.A. Tarasenko “Spin photocurrents in semiconductors53 739–742 (2010)
    75.76.+j, 78.56.−a, 85.75.−d (all)
  16. N.S. Averkiev “Spin relaxation anisotropy in two-dimensional semiconductors53 742–745 (2010)
    75.76.+j, 76.30.−v, 85.75.−d (all)
  17. Yu.V. Gulyaev, P.E. Zil’berman, E.M. Epshtein “Nano-sized structures incorporating ferromagnetic metal layers: new effects due to the passage of a perpendicular current51 409–412 (2008)
    72.25.−b, 75.75.+a, 85.75.−d (all)
  18. A.K. Zvezdin, K.A. Zvezdin, A.V. Khval’kovskii “The generalized Landau-Lifshitz equation and spin transfer processes in magnetic nanostructures51 412–417 (2008)
    72.25.−b, 75.75.+a, 85.75.−d (all)
  19. B.P. Zakharchenya, V.L. Korenev “Integrating magnetism into semiconductor electronics48 603–608 (2005)
    72.25.Pn, 78.67.−n, 85.75.−d (all)
  20. I.V. Kukushkin, V.B. Timofeev “Density of states of two-dimensional electrons in a quantizing transverse magnetic field30 746–747 (1987)
    71.70.Di, 73.40.Qv, 73.50.Jt, 71.15.Ap, 71.35.Lk (all)
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