PACS numbers

73.21.−b Electron states and collective excitations in multilayers, quantum wells, mesoscopic, and nanoscale systems 73.22.−f Electronic structure of nanoscale materials and related systems 73.43.Lp Collective excitations 78.70.Gq Microwave and radio-frequency interactions
  1. V.M. Murav’ev, I.V. Kukushkin “Collective plasma excitations in two-dimensional electron systems63 (10) (2020)
    73.21.−b, 73.22.−f, 73.43.Lp, 78.70.Gq (all)
  2. K.V. Reich “Conductivity of quantum dot arrays63 (10) (2020)
    71.30.+h, 72.10.−d, 72.15.Rn, 72.20.Ee, 72.80.Ng, 73.21.La, 73.22.−f, 73.23.Hk, 73.40.Gk, 81.07.Bc (all)
  3. L.A. Chernozatonskii, A.A. Artyukh “Quasi-two-dimensional transition metal dichalcogenides: structure, synthesis, properties and applications61 2–28 (2018)
  4. G.E. Volovik “Exotic Lifshitz transitions in topological materials61 89–98 (2018)
    04.70.−s, 71.30.+h, 73.22.−f (all)
  5. N.N. Sibeldin “Electron-hole liquid in semiconductors and low-dimensional structures60 1147–1179 (2017)
    71.35.−y, 73.20.Mf, 73.21.−b (all)
  6. 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)
  7. P.B. Sorokin, L.A. Chernozatonskii “Graphene-based semiconductor nanostructures56 105–122 (2013)
    73.22.−f, 73.22.Pr, 73.61.Ey, 81.05.ue (all)
  8. V.Ya. Pokrovskii, S.G. Zybtsev et alHigh-frequency, ’quantum’ and electromechanical effects in quasi-one-dimensional charge density wave conductors56 29–48 (2013)
    61.44.Fw, 62.25.−g, 71.45.Lr, 72.20.Fr, 73.20.Mf, 78.70.Gq (all)
  9. Plasmonics (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 21 February 2012)55 1035–1058 (2012)
    01.10.Fv, 33.50.Dq, 42.50.Nn, 42.55.Ah, 42.70.Nq, 71.45.−d, 73.20.Mf, 73.22.−f, 78.20.Ek, 78.67.Bf, 78.67.Pt, 81.05.Xj (all)
  10. Yu.E. Lozovik “Plasmonics and magnetoplasmonics based on graphene and a topological insulator55 1035–1039 (2012)
    71.45.−d, 73.20.Mf, 73.22.−f (all)
  11. Yu.E. Lozovik, S.P. Merkulova et alCollective electron phenomena and electron transport in graphene (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 27 February 2008)51 727–748 (2008)
    01.10.Fv, 71.35.Ji, 73.20.Mf, 73.21.−b, 72.80.Rj, 73.43.−f, 81.05.Uw (all)
  12. Yu.E. Lozovik, S.P. Merkulova, A.A. Sokolik “Collective electron phenomena in graphene51 727–744 (2008)
    71.35.Ji, 73.20.Mf, 73.21.−b (all)
  13. V.A. Cherepenin “Relativistic multiwave oscillators and their possible applications49 1097–1102 (2006)
    01.10.Fv, 78.70.Gq, 84.40.Fe, 84.47.+w (all)
  14. 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)
  15. A.V. Eletskii “Carbon nanotubes and their emission properties45 369–402 (2002)
    73.22.−f, 73.63.Fg, 81.07.De (all)
  16. E.L. Nagaev “Small metal particles35 (9) 747–782 (1992)
    61.46.Df, 01.30.Vv, 65.80.+n, 64.70.Dv, 73.22.−f, 75.50.Tt (all)
  17. V.V. Lemanov, G.A. Smolenskii “Hypersonic waves in crystals15 708–727 (1973)
    78.70.Gq, 78.35.+c, 63.20.Kr, 75.30.Ds, 75.80.+q, 72.20.Fr (all)
  18. L.A. Blyumenfel’d, V.V. Voevodskii “Radio spectroscopy and contemporary theoretical chemistry2 365–376 (1959)
    78.70.Gq, 76.30.−v, 76.60.Cq, 76.60.Gv, 82.30.−b (all)
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