PACS numbers

36.40.−c Atomic and molecular clusters 74.70.−b Superconducting materials other than cuprates 74.78.Na Mesoscopic and nanoscale systems
  1. G.N. Makarov “Control of the parameters and composition of molecular and cluster beams by means of IR lasers61 617–644 (2018)
    06.30.−k, 07.77.Gx, 33.80.−b, 36.40.−c, 41.75.Jv, 42.62.Fi, 82.50.Hp (all)
  2. K.V. Mitsen, O.M. Ivanenko “Superconducting phase diagrams of cuprates and pnictides as a key to understanding the HTSC mechanism60 402–411 (2017)
    74.20.Mn, 74.25.Dw, 74.72.−h, 74.70.−b (all)
  3. G.N. Makarov “Laser IR fragmentation of molecular clusters: the role of channels for energy input and relaxation, influence of surroundings, dynamics of fragmentation60 227–258 (2017)
    07.77.Gx, 33.80.−b, 36.40.−c, 37.20.+j, 42.62.Fi, 81.07.−b, 82.50.Bc (all)
  4. M.I. Eremets, A.P. Drozdov “High-temperature conventional superconductivity59 1154–1160 (2016)
    74.20.Fg, 74.62.Fj, 74.70.−b (all)
  5. M.V. Sadovskii “High-temperature superconductivity in monolayers FeSe59 947–967 (2016)
    74.20.−z, 74.20.Fg, 74.20.Mn, 74.20.Rp, 74.25.Jb, 74.62.−c, 74.70.−b (all)
  6. A.V. Samokhvalov, A.S. Mel’nikov, A.I. Buzdin “Long-range ballistic transport mechanisms in superconducting spintronics59 571–576 (2016)
    74.45.+c, 74.78.Na, 85.25.Cp (all)
  7. I.A. Sadovskyy “Reduction of the scattering matrix array58 872–876 (2015)
    72.10.Bg, 73.23.−b, 74.78.Na (all)
  8. G.N. Makarov “Low energy methods of molecular laser isotope separation58 670–700 (2015)
    07.77.Gx, 33.80.−b, 36.40.−c, 42.62.−b, 42.62.Fi, 82.40.Fp, 82.50.Bc (all)
  9. M. Ganeva, P.V. Kashtanov et alClusters as a diagnostics tool for gas flows58 579–588 (2015)
    36.40.−c, 47.15.−x, 47.85.L− (all)
  10. Yu.F. Eltsev, K.S. Pervakov et alMagnetic and transport properties of single crystals of Fe-based superconductors of 122 family57 827–832 (2014)
    74.25.−q, 74.45.+c, 74.70.−b (all)
  11. R.S. Berry, B.M. Smirnov “Modeling of configurational transitions in atomic systems56 973–998 (2013)
    36.40.−c, 36.40.Ei, 64.70.D−, 71.15.Mb, 81.16.Hc, 82.30.−b (all)
  12. 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)
  13. G.B. Lesovik, I.A. Sadovskyy “Scattering matrix approach to the description of quantum electron transport54 1007–1059 (2011)
    72.10.−d, 73.23.−b, 73.50.Td, 74.25.F−, 74.45.+c, 74.78.Na (all)
  14. B.M. Smirnov “Processes involving clusters and small particles in a buffer gas54 691–721 (2011)
    36.40.−c, 36.40.Sx, 61.43.Hv, 64.70.D−, 68.37.Hk (all)
  15. V.M. Pudalov, O.E. Omel’yanovskii et alV L Ginzburg and the development of experimental work on high-temperature superconductivity at LPI: ’iron superconductors’54 648–653 (2011)
    74.25.−q, 74.45.+c, 74.70.−b (all)
  16. G.N. Makarov “Kinetic methods for measuring the temperature of clusters and nanoparticles in molecular beams54 351–370 (2011)
    07.77.Gx, 36.40.−c, 36.40.Ei, 42.62.Fi, 81.07.Nb, 82.50.Hp (all)
  17. G.N. Makarov “Experimental methods for determining the melting temperature and the heat of melting of clusters and nanoparticles53 179–198 (2010)
    07.77.Gx, 32.80.−t, 36.40.−c, 36.40.Ei, 42.62.Fi, 81.07.−b (all)
  18. G.N. Makarov “The spectroscopy of clusters by intense pulses of VUV radiation from free electron lasers52 461–486 (2009)
    32.80.−t, 36.40.−c, 41.60.Cr, 42.55.Vc, 42.62.Fi, 52.50.−b, 82.50.Hp (all)
  19. V.I. Balykin, A.N. Ryabtsev et alOn the 40th anniversary of the Institute of Spectroscopy of the Russian Academy of Sciences (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 8 October 2008)52 275–309 (2009)
    03.75.−b, 03.75.Hh, 05.30.Jp, 07.07.−a, 32.30.−r, 32.30.Jc, 33.20.−t, 36.40.−c, 37.20.+j, 42.82.Cr, 61.43.−j, 63.20.−e, 63.50.−x, 67.25.dw, 71.35.Lk, 71.36.+c, 78.30.−j, 78.47.−p, 78.55.−m, 81.07.−b,, 87.64.−t, 95.30.Ky, 97.10.−q (all)
  20. B.S. Dumesh, A.V. Potapov, L.A. Surin “Spectroscopy of small helium clusters and ’nanoscopic’ superfluidity: HeN — CO, N = 2 — 20...52 294–298 (2009)
    05.30.Jp, 33.20.−t, 36.40.−c, 67.25.dw (all)
  21. M.V. Sadovskii “High-temperature superconductivity in iron-based layered compounds51 1201–1227 (2008)
    74.20.−z, 74.25.−q, 74.62.−c, 74.70.−b (all)
  22. Yu.A. Izyumov, E.Z. Kurmaev “FeAs systems: a new class of high-temperature superconductors51 1261–1286 (2008)
    74.20.−z, 74.25.−q, 74.62.−c, 74.70.−b (all)
  23. S.M. Stishov, L.G. Khvostantsev et alOn the 50th anniversary of the L F Vereshchagin Institute for High Pressure Physics, RAS (Scientific outreach session of the Physical Sciences Division of the Russian Academy of Sciences, 23 April 2008)51 1055–1083 (2008)
    01.65.+g, 07.35.+k, 61.50.Ks, 62.50.−p, 64.70.kd, 71.15.−m, 71.18.+y, 73.20.−r, 74.20.−z, 74.70.−b, 75.10.−b (all)
  24. L.N. Dzhavadov, E.L. Gromnitskaya et alStudies of the thermodynamic, elastic, superconducting, and magnetic properties of substances at high pressures51 1066–1070 (2008)
    61.50.Ks, 62.50.+p, 74.70.−b (all)
  25. V.Z. Kresin, Yu.N. Ovchinnikov “‘Giant’ strengthening of superconducting pairing in metallic nanoclusters: large enhancement of Tc and potential for room-temperature superconductivity51 427–435 (2008)
    36.40.−c, 74.70.−b, 74.78.Na (all)
  26. G.N. Makarov “Cluster temperature. Methods for its measurement and stabilization51 319–353 (2008)
    32.80.−t, 34.50.−s, 36.40.−c, 43.25.Cb, 79.20.Rf, 81.07.−b (all)
  27. E.V. Antipov, A.M. Abakumov “Structural design of superconductors based on complex copper oxides51 180–190 (2008)
    74.62.−c, 74.70.−b, 74.78.−w (all)
  28. V.P. Krainov, B.M. Smirnov, M.B. Smirnov “Femtosecond excitation of cluster beams50 907–931 (2007)
    36.40.−c, 52.40.Hf, 52.40.Mj, 61.46.−w (all)
  29. P.V. Kashtanov, B.M. Smirnov, R. Hippler “Magnetron plasma and nanotechnology50 455–488 (2007)
    36.40.−c, 52.80.Sm, 61.46.Bc (all)
  30. B.M. Smirnov “Clusters and phase transitions50 354–358 (2007)
    01.10.Fv, 36.40.−c, 61.46.Bc, 64.70.Dv (all)
  31. B.S. Dumesh, L.A. Surin “Unusual rotations in helium and hydrogen nanoclusters and ’nanoscopic’ superfluidity49 1113–1129 (2006)
    05.30.Jp, 33.20.−t, 36.40.−c, 67.40.−w (all)
  32. G.N. Makarov “On the possibility of selecting molecules embedded in superfluid helium nanodroplets (clusters)49 1131–1150 (2006)
    28.60.+s, 33.80.−b, 36.40.−c, 42.62.Fi (all)
  33. G.N. Makarov “Extreme processes in clusters impacting on a solid surface49 117–166 (2006)
    34.50.−s, 36.40.−c, 43.25.Cb, 79.20.Rf, 81.15.−z (all)
  34. V.P. Krainov, M.B. Smirnov “The evolution of large clusters under the action of ultrashort superintense laser pulses43 901–920 (2000)
    36.40.−c, 52.40.Nk, 61.46.+w, 85.42.+m (all)
  35. V.N. Bezmel’nitsyn, A.V. Eletskii, M.V. Okun’ “Fullerenes in solutions41 1091–1114 (1998)
    36.40.−c, 61.46.+w, 61.48.+c (all)
  36. S.A. Nemov, Yu.I. Ravich “Thallium dopant in lead chalcogenides: investigation methods and peculiarities41 735–759 (1998)
    71.20.−b, 71.55.−i, 74.70.−b, 78.90.+t (all)
  37. A.V. Eletskii, B.M. Smirnov “Fullerenes and carbon structures38 935–964 (1995)
    36.40.−c, 61.46.+w, 61.66.Bi, 74.70.Wz (all)
  38. E.F. Mikhailov, S.S. Vlasenko “The generation of fractal structures in gaseous phase38 253–271 (1995)
    36.40.−c, 47.53.+n, 61.43.Hv (all)
  39. A.N. Lykov “The mixed state in superconducting microstructures35 (10) 811–841 (1992)
    74.25.Op, 74.70.−b, 74.25.Qt, 74.25.Fy, 74.25.Sv, 74.78.−w (all)
  40. V.L. Ginzburg “Thermoelectric effects in the superconducting state34 (2) 101–107 (1991)
    74.25.Fy, 74.72.−h, 74.70.−b (all)
  41. A.V. Eletskii, B.M. Smirnov “Properties of cluster ions32 763–782 (1989)
    36.40.−c, 33.80.Gj (all)
  42. M.A. Obolenskii “Superconductivity and energy spectra of layered dichalcogenides of transition metals31 956–957 (1988)
    74.25.Op, 74.25.Kc, 74.70.−b, 74.62.−c (all)
  43. P.B. Wigman “High-temperature superconductivity in metal-oxide ceramics30 729–732 (1987)
    74.72.−h, 74.70.−b (all)
  44. A.M. Gabovich, D.P. Moiseev “Metal oxide superconductor BaPb1-xBixO3: unusual properties and new applications29 1135–1150 (1986)
    74.25.Dw, 74.25.Gz, 74.25.Bt, 74.70.−b, 74.50.+r, 61.66.Fn (all)
  45. A.I. Golovashkin “Superconductors with unusual properties and possibilities of increasing the critical temperature29 199–209 (1986)
    74.62.−c, 74.25.Kc, 74.25.Jb, 74.70.−b (all)
  46. I.O. Kulik “Superconductivity of narrow-band metals and semiconductors and the model of superconducting glass28 97–99 (1985)
    74.20.Fg, 74.25.Kc, 74.25.Ha, 74.25.Dw, 74.70.−b (all)
  47. B.T. Geilikman “Problems of high-temperature superconductivity in three-dimensional systems16 17–30 (1973)
    71.35.−y, 74.72.−h, 74.40.+k, 74.78.−w, 74.70.−b (all)
  48. N.M. Builova, V.B. Sandomirskii “Experimental investigations of superconductivity in degenerate semiconductors12 64–69 (1969)
    74.25.Jb, 74.70.−b, 74.10.+v (all)
  49. N.E. Alekseevskii “New superconductors11 403–410 (1968)
    74.70.−b, 74.10.+v, 74.78.−w, 64.70.−p (all)
  50. A.P. Levanyuk, R.A. Suris “Some properties of superconducting compounds of the V3Si type10 40–44 (1967)
    74.70.−b, 74.62.−c, 74.25.Ha, 74.25.Jb, 74.25.Ld (all)
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