PACS numbers

61.48.De Structure of carbon nanotubes, boron nanotubes, and other related systems 73.63.−b Electronic transport in nanoscale materials and structures 81.05.ue Graphene
  1. B.M. Smirnov “Metal nanostructures: from clusters to nanocatalysis and sensors60 (12) (2017)
    61.43.Hv, 61.46.−w, 72.15.−v, 73.63.−b (all)
  2. P.I. Arseev, V.N. Mantsevich et alTunneling features in semiconductor nanostructures60 (11) (2017)
    05.60.Gg, 68.37.Ef, 73.40.Gk, 73.63.−b (all)
  3. M.Yu. Kagan, V.A. Mitskan, M.M. Korovushkin “Anomalous superconductivity and superfluidity in repulsive fermion systems58 733–761 (2015)
    67.85.−d, 74.20.−z, 74.20.Mn, 74.20.Rp, 74.25.Dw, 74.78.Fk, 81.05.ue (all)
  4. M.V. Kharlamova “Electronic properties of pristine and modified single-walled carbon nanotubes56 1047–1073 (2013)
    61.46.Np, 61.48.De, 77.22.−d, 85.35.Kt (all)
  5. I.V. Antonova “Chemical vapor deposition growth of graphene on copper substrates: current trends56 1013–1020 (2013)
    68.65.Pq, 81.05.ue, 81.15.Gh, 81.16.Be (all)
  6. G.N. Makarov “Laser applications in nanotechnology: nanofabrication using laser ablation and laser nanolithography56 643–682 (2013)
    36.40.−c, 42.62.Fi, 61.46.−w, 81.05.ue, 81.07.−b, 81.16.−c, 81.16.Nd (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. Physical properties of graphene (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 28 March 2012)55 1140–1151 (2012)
    01.10.Fv, 65.80.Ck, 68.65.Pq, 72.15.Jf, 72.20.Pa, 72.80.Vp, 78.67.Wj, 81.05.ue (all)
  9. L.A. Falkovsky “Magnetooptics of graphene layers55 1140–1145 (2012)
    68.65.Pq, 78.67.Wj, 81.05.ue (all)
  10. A.A. Varlamov, A.V. Kavokin et alAnomalous thermoelectric and thermomagnetic properties of graphene55 1146–1151 (2012)
    65.80.Ck, 72.15.Jf, 72.20.Pa, 72.80.Vp, 81.05.ue (all)
  11. Modern problems in physical sciences (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 26 October 2011)55 408–425 (2012)
    01.10.Fv, 42.25.−p, 42.30.−d, 42.60.Jf, 72.80.Vp, 73.20.−r, 75.30.−m, 75.50.−y, 81.05.Bx, 81.05.ue (all)
  12. S.V. Morozov “New effects in graphene with high carrier mobility55 408–412 (2012)
    72.80.Vp, 73.20.−r, 81.05.ue (all)
  13. A.I. Vorob’eva “Equipment and techniques for carbon nanotube research53 257–277 (2010)
    61.48.De, 73.63.−b, 81.05.ue (all)
  14. A.I. Romanenko, A.V. Okotrub et alHeterogeneous electronic states in carbon nanostructures with different dimensionalities and curvatures of the constituent graphene layers48 958–962 (2005)
    72.15.Gd, 72.15.Rn, 73.63.−b, 73.63.Bd, 73.63.Fg (all)
  15. V.V. Belov, S.Yu. Dobrokhotov et alA generalized adiabatic principle for electron dynamics in curved nanostructures48 962–968 (2005)
    03.65.Ge, 03.65.Nk, 73.63.−b (all)
  16. V.B. Timofeev “Electron correlation phenomena in semiconductor low-dimension structures and nanostructures47 1037–1044 (2004)
    71.35.−y, 71.36.+c, 73.43.−f, 73.63.−b (all)
  17. A.A. Andronov, M.N. Drozdov et alTransport in weak barrier superlattices and the problem of the terahertz Bloch oscillator46 755–758 (2003)
    42.55.Px, 71.70.Ej, 73.63.−b (all)
  18. A.P. Silin “Heterojunctions and semiconductor superlattices30 753–754 (1987)
    01.30.Vv, 73.63.−b, 73.21.Cd, 73.40.−c (all)
  19. A.M. Belyantsev, Yu.A. Romanov “The classical superlattice—an artificial dielectric, nonlinear hf effect28 521–522 (1985)
    72.20.Ht, 73.63.−b, 72.80.Ey (all)
  20. Z.D. Kvon, I.G. Neizvestnyi, V.N. Ovsyuk “Effect of a surface superlattice on a two-dimensional electron gas28 528–530 (1985)
    73.21.Cd, 73.20.At, 73.63.−b (all)
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