PACS numbers

05.60.Gg Quantum transport 68.37.Ef Scanning tunneling microscopy (including chemistry induced with STM) 73.40.Gk Tunneling 73.63.−b Electronic transport in nanoscale materials and structures
  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 1067–1086 (2017)
    05.60.Gg, 68.37.Ef, 73.40.Gk, 73.63.−b (all)
  3. P.I. Arseev “On the nonequilibrium diagram technique: derivation, some features and applications58 1159–1205 (2015)
    03.70.+k, 05.60.Gg, 11.10.Wx, 72.10.Bg (all)
  4. T. Konstandin “Quantum transport and electroweak baryogenesis56 747–771 (2013)
    05.60.Gg, 12.15.−y, 12.60.Jv (all)
  5. P.I. Arseev, N.S. Maslova “Electron — vibration interaction in tunneling processes through single molecules53 1151–1169 (2010)
    73.23.−b, 73.40.Gk, 74.55.+v (all)
  6. A.I. Vorob’eva “Equipment and techniques for carbon nanotube research53 257–277 (2010)
    61.48.De, 73.63.−b, 81.05.ue (all)
  7. L.V. Arapkina, V.A. Yuryev “Classification of Ge hut clusters in arrays formed by molecular beam epitaxy at low temperatures on the Si(001) surface53 279–290 (2010)
    68.37.Ef, 81.07.Ta, 81.15.Hi (all)
  8. A.A. Shklyaev, M. Ichikawa “Fabrication of germanium and silicon nanostructures using a scanning tunneling microscope49 887–903 (2006)
    68.37.Ef, 79.70.+q, 81.16.Ta (all)
  9. V.S. Edel’man “Scanning tunnel microscopy and spectroscopy of an atomically clean bismuth surface48 1057–1061 (2005)
    65.35.-p, 68.37.−d, 68.37.Ef (all)
  10. 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)
  11. 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)
  12. 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)
  13. 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)
  14. A.V. Vedyaev “Use of spin-polarized current in spintronics45 1296–1299 (2002)
    73.40.Gk, 73.40.Rw, 75.70.−i, 85.30.Mn (all)
  15. E.E. Vdovin, Yu.N. Khanin et alMagnetotunneling spectroscopy imaging of electron wave functions in self-assembled InAs quantum dots44 1299–1301 (2001)
    71.24.+q, 73.40.Gk, 73.61.Ey, 73.61.Tm (all)
  16. E.E. Vdovin, Yu.N. Khanin et alScientific session of the Division of General Physics and Astronomy of the Russian Academy of Sciences (30 May 2001)44 1299–1301 (2001)
    71.24.+q, 73.40.Gk, 73.61.Ey, 73.61.Tm, 71.45.Gm, 71.55.Eq, 73.20.Mf, 73.61.−r, 85.30.Vw, 85.30.Tv, 03.75.Fi, 71.35.Lk, 71.35.Ji, 29.25.Bx, 29.27.Hj, 79.60.Jv (all)
  17. V.A. Volkov, E.E. Takhtamirov et alTunneling spectroscopy of quasi-two-dimensional plasmons44 1301–1304 (2001)
    71.45.Gm, 71.55.Eq, 73.20.Mf, 73.40.Gk (all)
  18. V.F. Elesin, I.Yu. Kateev et alTheory of coherent oscillations in a resonant tunneling diode43 291–293 (2000)
    73.20.−r, 73.23.−b, 73.40.Gk (all)
  19. V.N. Murzin, Yu.A. Mityagin “Resonance tunneling, electric and optical phenomena in long-period semiconductor superlattices42 396–399 (1999)
    73.20.Dx, 73.40.Gk
  20. M.Ya. Azbel’ “Time, tunneling and turbulence41 543–552 (1998)
    72.15.Rn, 72.80.Ng, 73.40.Gk (all)
  21. L. Vina, M. Potemski, W.I. Wang “Signatures of quantum chaos in the magneto-excitonic spectrum of quantum wells41 153–156 (1998)
    05.45.+b, 73.40.Gk
  22. V.I. Fal’ko “Image of local density of states in differential conductance fluctuations in the resonance tunneling between disordered metals41 156–159 (1998)
    05.45.+b, 73.40.Gk
  23. J. Koenig, H. Schoeller, G. Schon “Resonant tunneling through a single-electron transistor41 159–164 (1998)
    05.45.+b, 73.40.Gk
  24. Z.D. Kvon, E.B. Olshanetskii et alCoulomb-like mesoscopic conductance fluctuations in a 2D electron gas near the filling factor ν = 1/241 164–166 (1998)
    05.45.+b, 73.40.Gk
  25. V.A. Krupenin, S.V. Lotkhov et alAn experimental study of charge effects in ultrasmall tunnel junctions40 542–544 (1997)
    73.40.Gk, 73.40.Rw (all)
  26. N.S. Maslova “Chemistry and physics of solid surfaces34 (4) 359–359 (1991)
    68.37.Ef, 68.37.Ps, 68.47.Fg (all)
  27. V.S. Edel’man “The development of scanning tunneling microscopy34 (3) 272–273 (1991)
    07.79.Cz, 68.37.Ef, 72.40.+w, 78.55.Cr, 74.72.Bk, 78.67.Pt (all)
  28. V.I. Panov “Scanning tunneling microscopy and surface spectroscopy31 471–473 (1988)
    68.37.Ef, 66.30.Fq, 68.35.Bs, 68.47.De, 73.20.At (all)
  29. M.S. Khaikin “Scanning tunneling microscopy and spectroscopy31 473–474 (1988)
    68.37.Ef, 73.30.+y, 68.35.Bs, 74.72.Bk, 74.50.+r (all)
  30. V.M. Svistunov, M.A. Belogolovskii, A.I. D’yachenko “Vacuum tunneling microscopy and spectroscopy31 86–89 (1988)
    07.79.Cz, 01.10.Cr, 68.37.Ef, 68.35.Bs, 74.25.Jb, 74.50.+r (all)
  31. A.P. Silin “Heterojunctions and semiconductor superlattices30 753–754 (1987)
    01.30.Vv, 73.63.−b, 73.21.Cd, 73.40.−c (all)
  32. 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)
  33. 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)
  34. I.P. Revokatova, A.P. Silin “Scanning tunneling microscopy: new method for studying solid surfaces27 76–78 (1984)
    07.79.Cz, 68.37.Ef (all)
  35. L.V. Iogansen “Thin-film electron interferometers8 413–416 (1965)
    85.30.Mn, 73.50.−h, 73.40.Gk, 84.47.+w (all)
  36. V.I. Fistul’, N.Z. Shvarts “TUNNEL DIODES5 430–459 (1962)
    85.30.Mn, 73.40.Gk, 73.40.Kp, 85.30.De (all)
  37. P.V. Ratnikov, A.P. Silin “Two-dimensional graphene electronics: current state and prospects”, accepted
    68.65.Pq, 68.65.Cd, 73.21.Fg, 73.40.Gk, 73.50.−h, 85.30.Tv, 85.40.−e, 85.60.−q, 85.65.+h (all)
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