PACS numbers

36.40.−c Atomic and molecular clusters 36.40.Sx Diffusion and dynamics of clusters 61.43.Hv Fractals; macroscopic aggregates (including diffusion-limited aggregates) 64.70.D− Solid-liquid transitions 68.37.Hk Scanning electron microscopy (SEM) (including EBIC)
  1. G.N. Makarov “New approaches to molecular laser separation of uranium isotopes67 44–54 (2024)
    07.77.Gx, 28.60.+s, 33.80-b, 36.40.−c, 42.62.−b, 42.62.Fi, 82.50.Bc (all)
  2. I.G. Dyachkova, D.A. Zolotov et alPotential of the microwave method for the activation of carbon materials in comparison with the traditional thermal method66 1248–1257 (2023)
    61.05.C−, 68.37.Hk, 68.37.Lp, 78.70.Gq (all)
  3. A.E. Ieshkin, A.B. Tolstoguzov et alGas-dynamic sources of cluster ions for basic and applied research65 677–705 (2022)
    29.25.Ni, 36.40.−c, 41.75.−i, 68.49.Sf (all)
  4. G.N. Makarov “Towards molecular laser separation of uranium isotopes65 531–566 (2022)
    07.77.Gx, 28.60.+s, 33.80.−b, 36.40.−c, 42.62.−b, 42.62.Fi, 82.50.Bc (all)
  5. A.I. Savvatimskiy, S.V. Onufriev, N.M. Aristova “Physical properties of refractory carbides of metals of groups IV and V of the Mendeleev periodic table during rapid heating by an electric current pulse65 597–616 (2022)
    64.70.D−, 65.40.−b, 81.05.Je (all)
  6. D.K. Belashchenko “Does the embedded atom model have predictive power?63 1161–1187 (2020)
    02.70.−c, 64.30.−t, 64.70.D− (all)
  7. A.I. Savvatimskii, S.V. Onufriev “Investigation of the physical properties of carbon under high temperatures (experimental studies)63 1015–1036 (2020)
    05.70.−a, 64.70.D−, 65.40.Ba (all)
  8. V.N. Ryzhov, E.E. Tareyeva et alComplex phase diagrams of systems with isotropic potentials: results of computer simulations63 417–439 (2020)
    02.70.Ns, 64.10.+h, 64.70.D− (all)
  9. 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)
  10. S.M. Stishov “Quantum effects in a system of Boltzmann hard spheres62 617–622 (2019)
    64.70.D−, 67.10.Fj (all)
  11. S.A. Aseyev, E.A. Ryabov “Investigation of structural dynamics of substances using ultrafast electron diffraction and microscopy62 289–293 (2019)
    07.78.+s, 61.05.J−, 64.70.D−, 64.70.K−, 68.37.Og (all)
  12. 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)
  13. B.M. Smirnov “Metal nanostructures: from clusters to nanocatalysis and sensors60 1236–1267 (2017)
    61.43.Hv, 61.46.−w, 72.15.−v, 73.63.−b (all)
  14. V.N. Ryzhov, E.E. Tareyeva et alBerezinskii—Kosterlitz—Thouless transition and two-dimensional melting60 857–885 (2017)
    02.70.Ns, 05.70.Ln, 64.10.+h, 64.60.Ej, 64.70.D− (all)
  15. 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)
  16. 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)
  17. 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)
  18. G.V. Kozlov “Structure and properties of particulate-filled polymer nanocomposites58 33–60 (2015)
    61.43.Hv, 61.46.Df, 62.20.de, 62.23.Pq (all)
  19. A.A. Ishchenko, S.A. Aseev et alUltrafast electron diffraction and electron microscopy: present status and future prospects57 633–669 (2014)
    07.78.+s, 61.05.J−, 64.70.D−, 64.70.K−, 68.37.Og (all)
  20. 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)
  21. 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)
  22. 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)
  23. 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)
  24. B.A. Klumov “On melting criteria for complex plasma53 1053–1065 (2010)
    52.27.Lw, 52.65.Yy, 61.72.J−, 64.70.D− (all)
  25. 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)
  26. 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)
  27. 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)
  28. 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)
  29. 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)
  30. 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)
  31. 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)
  32. 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)
  33. B.M. Smirnov “Clusters and phase transitions50 354–358 (2007)
    01.10.Fv, 36.40.−c, 61.46.Bc, 64.70.Dv (all)
  34. 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)
  35. 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)
  36. 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)
  37. B.M. Smirnov “Generation of cluster beams46 589–628 (2003)
    36.40.Sx, 36.40.Wa, 52.50.Jm, 61.46.+w (all)
  38. G.V. Kozlov, V.U. Novikov “A cluster model for the polymer amorphous state44 681–724 (2001)
    61.41.+e, 61.43.−j, 61.43.Bn, 61.43.Hv, 61.46.+w (all)
  39. 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)
  40. 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)
  41. 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)
  42. V.V. Zosimov, L.M. Lyamshev “Fractals in wave processes38 347–384 (1995)
    47.35.+i, 47.52.+j, 47.53.+n, 61.43.Hv (all)
  43. 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)
  44. E.P. Emets, A.E. Novoselova, P.P. Poluektov “In situ determination of the fractal dimensions of aerosol particles37 881–887 (1994)
    61.43.Hv, 47.53.+n, 82.70.Rr, 92.60.Mt (all)
  45. A.I. Olemskoi, A.Ya. Flat “Application of fractals in condensed-matter physics36 (12) 1087–1128 (1993)
    64.60.Ak, 47.53.+n, 61.43.Hv, 61.44.−n (all)
  46. B.M. Smirnov “Radiative processes involving fractal structures36 (7) 592–603 (1993)
    61.43.Hv, 52.80.−s (all)
  47. B.M. Smirnov “Energetic processes in macroscopic fractal structures34 (6) 526–541 (1991)
    61.43.Hv, 68.35.Md, 82.70.Gg (all)
  48. A.A. Lushnikov, A.E. Negin et alAerogel structures in a gas34 (2) 160–166 (1991)
    61.43.Gt, 61.43.Hv, 61.80.Ba (all)
  49. B.M. Smirnov “Phenomena of growth of fractal systems32 941–942 (1989)
    01.30.Vv, 61.43.Hv, 47.53.+n (all)
  50. A.V. Eletskii, B.M. Smirnov “Properties of cluster ions32 763–782 (1989)
    36.40.−c, 33.80.Gj (all)
  51. B.M. Smirnov “Properties of a fractal aggregate32 181–182 (1989)
    61.43.Hv, 61.43.Bn, 68.43.Jk (all)
  52. N.S. Maslova, V.I. Panov “Scanning tunneling microscopy of atomic structure, electronic properties, and surface chemical reactions32 93–99 (1989)
    68.37.Hk, 68.35.Bs, 73.20.At, 68.43.−h, 82.65.+r (all)
  53. V.G. Dyukov “Scanning electron microscopy30 552–552 (1987)
    68.37.Hk
  54. B.M. Smirnov “Fractal clusters29 481–505 (1986)
    61.43.Hv, 68.43.Jk, 82.70.Rr, 66.30.Dn (all)
  55. G.V. Spivak, G.V. Saparin, M.K. Antoshin “Color contrast in scanning electron microscopy17 593–595 (1975)
    68.37.Hk, 78.60.Hk, 07.68.+m (all)
  56. G.V. Spivak, G.V. Saparin, M.V. Bykov “Scanning electron microscopy12 756–776 (1970)
    07.78.+s, 68.37.Hk, 78.60.Hk, 61.72.Ff, 87.64.Ee (all)
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