PACS numbers

72.25.Pn Current-driven spin pumping 78.67.−n Optical properties of low-dimensional, mesoscopic, and nanoscale materials and structures 85.75.−d Magnetoelectronics; spintronics: devices exploiting spin polarized transport or integrated magnetic fields
  1. S.A. Nikitov, A.R. Safin et alDielectric magnonics: from gigahertz to terahertz63 (10) (2020)
    85.70.−w, 85.75.−d (all)
  2. M.V. Rybin, M.F. Limonov “Once again about supercavity modes (a response to the letter to the editors of Physics-Uspekhi from V.V. Klimov [Phys. Usp. 62 (10) (2019); Usp. Fiz. Nauk 189 (10) 1131 (2019)] with comments on the review by M.V. Rybin and M.F. Limonov "Resonance effects in photonic crystals and metamaterials" [Phys. Usp. 62 (8) 823 (2019); Usp. Fiz. Nauk 189 (8) 881 (2019)])62 1279–1281 (2019)
    42.25.−p, 42.70.Qs, 78.67.−n (all)
  3. V.V. Klimov “On the existence of 'super-resonant' states in sub-wavelength dielectric resonators and their relation to bound states in the continuum62 1058–1059 (2019)
    42.25.−p, 42.70.Qs, 78.67.−n, 78.67.Pt (all)
  4. 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)
  5. P.N. Melentiev, V.I. Balykin “Nano optical elements for surface plasmon waves62 267–274 (2019)
    68.65.−k, 73.20.Mf, 78.67.−n (all)
  6. S.I. Lepeshov, A.E. Krasnok et alHybrid nanophotonics61 1035–1050 (2018)
    42.25.−p, 42.79.−e, 78.67.−n (all)
  7. M.V. Durnev, M.M. Glazov “Excitons and trions in two-dimensional semiconductors based on transition metal dichalcogenides61 825–845 (2018)
    71.35.−y, 73.20.Mf, 78.67.−n (all)
  8. V.I. Balykin, P.N. Melentiev “Optics and spectroscopy of a single plasmonic nanostructure61 133–156 (2018)
    68.65.−k, 73.20.Mf, 78.67.−n (all)
  9. M.A. Remnev, V.V. Klimov “Metasurfaces: a new look at Maxwell's equations and new ways to control light61 157–190 (2018)
    42.25.Fx, 42.65.−k, 42.70.−a, 42.79.−e, 68.65.−k, 78.67.−n, 78.67.Pt (all)
  10. 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)
  11. 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)
  12. I.S. Osad’ko “Blinking fluorescence of single semiconductor nanocrystals: basic experimental facts and the theoretical models of blinking59 462–474 (2016)
    33.50.−j, 33.70.−w, 78.67.−n (all)
  13. 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)
  14. 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)
  15. V.E. Bisti, A.B. Van’kov et alMagnetoexcitons in two-dimensional electronic systems58 315–329 (2015)
    73.20.Mf, 73.43.Lp, 78.67.−n (all)
  16. V.I. Balykin “Quantum control of atoms and photons by optical nanofibers57 607–615 (2014)
    42.50.Ex, 42.81.−i, 78.67.−n (all)
  17. 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)
  18. A.A. Fraerman “Magnetic states and transport properties of ferromagnetic nanostructures55 1255–1260 (2012)
    75.47.−m, 75.75.−c, 85.75.−d (all)
  19. Modern problems in the physical sciences (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 30 November 2011)55 808–837 (2012)
    01.10.Fv, 04.20.−q, 04.70.−s, 47.27.Gs, 47.35.Pq, 68.03.Kn, 72.25.Hg, 72.25.Pn, 72.25.Rb, 71.35.−y, 73.63.Hs, 78.47.−p, 78.67.−n, 96.50.−e, 96.60.−j, 95.75.−z, 98.80.−k (all)
  20. E.L. Ivchenko “Spin physics in semiconductor nanosystems55 809–814 (2012)
    71.35.−y, 78.47.−p, 78.67.−n (all)
  21. L.E. Golub “Spin transport in heterostructures55 814–818 (2012)
    72.25.Hg, 72.25.Pn, 72.25.Rb, 73.63.Hs (all)
  22. A.P. Pyatakov, A.K. Zvezdin “Magnetoelectric and multiferroic media55 557–581 (2012)
    75.85.+t, 85.70.−w, 85.75.−d (all)
  23. N.V. Volkov “Spintronics: manganite-based magnetic tunnel structures55 250–269 (2012)
    72.25.−b, 75.76.+j, 85.75.−d (all)
  24. Electromagnetic and acoustic waves in metamaterials and structures (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 24 February 2011)54 1161–1192 (2011)
    01.10.Fv, 03.65.Xp, 41.20.Jb, 42.25.−p, 43.20.+g, 43.20.Dk, 43.20.Fn, 43.25.+y, 43.30.+m, 43.60.−c, 43.60.Pt, 78.20.Ci, 78.67.−n, 81.05.Xi, 81.05.Zx, 87.50.Y (all)
  25. A.B. Shvartsburg, N.S. Erokhin “Resonant tunneling of ultrashort electromagnetic pulses in gradient metamaterials: paradoxes and prospects54 1171–1176 (2011)
    03.65.Xp, 42.25.−p, 78.67.−n (all)
  26. Celebrating 50 years of the laser (Scientific session of the General Meeting of the Physical Sciences Division of the Russian Academy of Sciences, 13 December 2010)54 837–870 (2011)
    01.10.Fv, 03.75.−b, 07.57.−c, 32.30.Jc, 37.10.−x, 37.10.De, 37.10.Gh, 42.62.−b, 42.65.−k, 42.70.−a, 42.82.−m, 67.85.−d, 78.67.−n, 85.40.−e, 84.40.Ik (all)
  27. Yu.N. Kulchin “The photonics of self-organizing biomineral nanostructures54 858–863 (2011)
    42.65.−k, 42.70.−a, 78.67.−n (all)
  28. Yu.G. Kusrayev “Spin phenomena in semiconductors: physics and applications53 725–738 (2010)
    75.47.−m, 75.76.+j, 85.75.−d (all)
  29. S.A. Tarasenko “Spin photocurrents in semiconductors53 739–742 (2010)
    75.76.+j, 78.56.−a, 85.75.−d (all)
  30. N.S. Averkiev “Spin relaxation anisotropy in two-dimensional semiconductors53 742–745 (2010)
    75.76.+j, 76.30.−v, 85.75.−d (all)
  31. T.V. Shubina, S.V. Ivanov et alPlasmon effects in In(Ga)N-based nanostructures52 949–953 (2009)
    36.40.Gk, 73.20.Mf, 78.67.−n (all)
  32. V.V. Kurin “Resonance scattering of light in nanostructured metallic and ferromagnetic films52 953–959 (2009)
    42.25.Fx, 78.20.Ls, 78.67.−n (all)
  33. A.N. Lagarkov, A.K. Sarychev et alSuperresolution and enhancement in metamaterials52 959–967 (2009)
    42.25.Gy, 42.55.−f, 78.67.−n (all)
  34. 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)
  35. 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)
  36. L.V. Kulik, V.E. Kirpichev “Inelastic light scattering spectroscopy of electron systems in single and double quantum wells49 353–368 (2006)
    73.21.−b, 73.22.−f, 73.43.Lp, 78.67.−n (all)
  37. I.S. Osad’ko “Blinking fluorescence of single molecules and semiconductor nanocrystals49 19–51 (2006)
    33.50.−j, 33.70.−w, 78.67.−n (all)
  38. B.P. Zakharchenya, V.L. Korenev “Integrating magnetism into semiconductor electronics48 603–608 (2005)
    72.25.Pn, 78.67.−n, 85.75.−d (all)
  39. V.D. Kulakovskii, D.N. Krizhanovskii et alPolariton-polariton scattering and the nonequilibrium condensation of exciton polaritons in semiconductor microcavities46 967–971 (2003)
    71.36.+c, 78.67.−n (all)
  40. V.V. Klimov “Spontaneous atomic radiation in the presence of nanobodies46 979–984 (2003)
    41.20.−q, 78.67.−n (all)
  41. I.V. Kukushkin, V.B. Timofeev “Magnetooptics of two-dimensional electrons in the ultraquantum limit34 (3) 269–272 (1991)
    01.30.Cc, 78.20.Ls, 73.43.Cd, 78.67.−n (all)
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