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 “New results for laser isotope separation using low-energy methods63 245–268 (2020)
    07.77.Gx, 33.80.−b, 36.40.−c, 42.62.−b, 42.62.Fi, 82.40.Fp, 82.50.Bc (all)
  2. 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)
  3. 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)
  4. 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)
  5. M.I. Eremets, A.P. Drozdov “High-temperature conventional superconductivity59 1154–1160 (2016)
    74.20.Fg, 74.62.Fj, 74.70.−b (all)
  6. 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)
  7. 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)
  8. I.A. Sadovskyy “Reduction of the scattering matrix array58 872–876 (2015)
    72.10.Bg, 73.23.−b, 74.78.Na (all)
  9. 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)
  10. 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)
  11. 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)
  12. 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)
  13. 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)
  14. 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)
  15. 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)
  16. 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)
  17. 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)
  18. 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)
  19. 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)
  20. 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, 87.85.fk, 87.64.−t, 95.30.Ky, 97.10.−q (all)
  21. 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)
  22. 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)
  23. 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)
  24. 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)
  25. 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)
  26. 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)
  27. 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)
  28. 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)
  29. 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)
  30. 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)
  31. B.M. Smirnov “Clusters and phase transitions50 354–358 (2007)
    01.10.Fv, 36.40.−c, 61.46.Bc, 64.70.Dv (all)
  32. 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)
  33. 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)
  34. 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)
  35. 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)
  36. 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)
  37. 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)
  38. 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)
  39. 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)
  40. 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)
  41. V.L. Ginzburg “Thermoelectric effects in the superconducting state34 (2) 101–107 (1991)
    74.25.Fy, 74.72.−h, 74.70.−b (all)
  42. A.V. Eletskii, B.M. Smirnov “Properties of cluster ions32 763–782 (1989)
    36.40.−c, 33.80.Gj (all)
  43. 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)
  44. P.B. Wigman “High-temperature superconductivity in metal-oxide ceramics30 729–732 (1987)
    74.72.−h, 74.70.−b (all)
  45. 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)
  46. 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)
  47. 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)
  48. 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)
  49. 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)
  50. N.E. Alekseevskii “New superconductors11 403–410 (1968)
    74.70.−b, 74.10.+v, 74.78.−w, 64.70.−p (all)
  51. 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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