PACS numbers

73.63.−b Electronic transport in nanoscale materials and structures
  1. A.I. Vorob’eva “Equipment and techniques for carbon nanotube research53 257–277 (2010)
    61.48.De, 73.63.−b, 81.05.ue (all)
  2. 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)
  3. 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)
  4. 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)
  5. 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)
  6. A.P. Silin “Heterojunctions and semiconductor superlattices30 753–754 (1987)
    01.30.Vv, 73.63.−b, 73.21.Cd, 73.40.−c (all)
  7. 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)
  8. 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)
  9. P.I. Arseev, V.N. Mantsevich et alTunneling processes peculiarities in the semiconductor nanostructures”, accepted
    68.37.Ef, 05.60.Gg, 73.40.Gk, 73.63.−b (all)
  10. B.M. Smirnov “Metal nanostructures: from clusters to nanocatalysis and sensors”, accepted
    61.43.Hv, 61.46.+w, 72.15.−v, 73.63.−b (all)
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