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Makarov, Grigorii Nikolaevich
Statistics Math-Net.Ru
Total publications: 58
Scientific articles: 58

Number of views:
This page:2380
Abstract pages:14590
Full texts:4310
References:1126
Main Scientist Researcher
Doctor of physico-mathematical sciences
E-mail:
Keywords: atoms, molecules, clusters, uranium, molecular and cluster beams, laser spectroscopy, laser-induced selective processes in molecules and clusters, laser separation of isotopes, laser physics.

https://www.mathnet.ru/eng/person45215
List of publications on Google Scholar
List of publications on ZentralBlatt

Publications in Math-Net.Ru Citations
2024
1. G. N. Makarov, “New approaches to molecular laser separation of uranium isotopes”, UFN, 194:1 (2024),  48–59  mathnet; Phys. Usp., 67:1 (2024), 44–54  isi  scopus
2023
2. G. N. Makarov, A. N. Petin, “Increase in the efficiency of the isotope-selective infrared laser multiphoton dissociation of $^{11}$BCl$_3$ molecules in a mixture with SF$_6$ serving as a sensitizer and an acceptor of radicals”, Pis'ma v Zh. Èksper. Teoret. Fiz., 117:10 (2023),  734–739  mathnet; JETP Letters, 117:10 (2023), 736–741
2022
3. G. N. Makarov, “On the possibility of the effective isotope-selective infrared dissociation of $^{235}$UF$_6$ molecules vibrationally excited by bichromatic laser radiation”, Pis'ma v Zh. Èksper. Teoret. Fiz., 115:11 (2022),  703–709  mathnet; JETP Letters, 115:11 (2022), 660–666 1
4. G. N. Makarov, A. N. Petin, “Intense infrared laser-induced radiation-collision involvement of molecules that do not absorb laser radiation in resonance with a laser field in a two-component molecular medium”, Pis'ma v Zh. Èksper. Teoret. Fiz., 115:5 (2022),  292–296  mathnet; JETP Letters, 115:5 (2022), 256–260 4
5. G. N. Makarov, “Towards molecular laser separation of uranium isotopes”, UFN, 192:6 (2022),  569–608  mathnet; Phys. Usp., 65:6 (2022), 531–566  isi  scopus 6
2021
6. G. N. Makarov, “Possibility of resonant three-photon isotope-selective excitation of vibrational states with v = 3 of the UF$_6$ molecule mode $\nu_3$ by radiation from two pulsed IR lasers in a gas-dynamically cooled molecular flow”, Kvantovaya Elektronika, 51:7 (2021),  643–648  mathnet  elib [Quantum Electron., 51:7 (2021), 643–648  isi  scopus] 4
2020
7. G. N. Makarov, A. N. Petin, “Strong increase in the efficiency of isotope-selective infrared laser dissociation of molecules under nonequilibrium thermodynamic conditions in a shock wave by means of the use of a mixture with a resonantly absorbing gas”, Pis'ma v Zh. Èksper. Teoret. Fiz., 112:4 (2020),  226–232  mathnet  elib; JETP Letters, 112:4 (2020), 213–218  isi  scopus 10
8. G. N. Makarov, A. N. Petin, “Isotope-selective infrared laser dissociation of molecules with a small isotopic shift in a gas-dynamically cooled molecular flow interacting with a solid surface”, Pis'ma v Zh. Èksper. Teoret. Fiz., 111:6 (2020),  361–369  mathnet  elib; JETP Letters, 111:6 (2020), 325–332  isi  scopus 9
9. G. N. Makarov, A. N. Petin, “Strong mutual increase in the efficiency of isotope-selective laser IR dissociation of molecules under nonequilibrium thermodynamic conditions of the compression shock under irradiation in a bimolecular mixture”, Kvantovaya Elektronika, 50:11 (2020),  1036–1042  mathnet  elib [Quantum Electron., 50:11 (2020), 1036–1042  isi  scopus] 6
10. G. N. Makarov, “New results for laser isotope separation using low-energy methods”, UFN, 190:3 (2020),  264–290  mathnet  elib; Phys. Usp., 63:3 (2020), 245–268  isi  scopus 14
2019
11. V. M. Apatin, V. N. Lokhman, G. N. Makarov, A. L. Malinovsky, A. N. Petin, N. D. Ogurok, D. G. Poidashev, E. A. Ryabov, “Isotope selective control over clustering of SF$_6$ molecules and dissociation of (SF$_{6}$)$_{m}$Ar$_{n}$ van der Waals clusters using an IR laser”, Optics and Spectroscopy, 127:1 (2019),  66–73  mathnet  elib; Optics and Spectroscopy, 127:1 (2019), 61–68 5
12. A. N. Petin, G. N. Makarov, “Infrared laser-induced isotope-selective dissociation of mixed (CF<sub>3</sub>Br) <sub>m</sub>Ar<sub>n</sub> van der Waals clusters”, Kvantovaya Elektronika, 49:6 (2019),  593–599  mathnet  elib [Quantum Electron., 49:6 (2019), 593–599  isi  scopus] 11
2018
13. G. N. Makarov, N. D. Ogurok, A. N. Petin, “Suppression of clustering of CF<sub>3</sub>Br molecules with argon atoms by CO<sub>2</sub>-laser radiation in gas-dynamic expansion of a CF<sub>3</sub>Br – Ar mixture: bromine isotope selectivity”, Kvantovaya Elektronika, 48:7 (2018),  667–674  mathnet  elib [Quantum Electron., 48:7 (2018), 667–674  isi  scopus] 14
14. V. M. Apatin, V. N. Lokhman, G. N. Makarov, N. D. Ogurok, E. A. Ryabov, “Brome isotope selective control of CF<sub>3</sub>Br molecule clustering by IR laser radiation in gas-dynamic expansion of CF<sub>3</sub>Br – Ar mixture”, Kvantovaya Elektronika, 48:2 (2018),  157–164  mathnet  elib [Quantum Electron., 48:2 (2018), 157–164  isi  scopus] 24
15. G. N. Makarov, “Control of the parameters and composition of molecular and cluster beams by means of IR lasers”, UFN, 188:7 (2018),  689–719  mathnet  elib; Phys. Usp., 61:7 (2018), 617–644  isi  scopus 11
2017
16. G. N. Makarov, “Laser IR fragmentation of molecular clusters: the role of channels for energy input and relaxation, the influence of surroundings, and the dynamics of fragmentation”, UFN, 187:3 (2017),  241–276  mathnet  elib; Phys. Usp., 60:3 (2017), 227–258  isi  scopus 15
2016
17. V. M. Apatin, V. N. Lokhman, G. N. Makarov, A. L. Malinovsky, A. N. Petin, D. G. Poidashev, E. A. Ryabov, “Determination of the composition and content of pulsed cluster beams from time-of-flight mass spectra of cluster fragments”, Pis'ma v Zh. Èksper. Teoret. Fiz., 104:6 (2016),  440–445  mathnet  elib; JETP Letters, 104:6 (2016), 425–430  isi  scopus 7
18. G. N. Makarov, A. N. Petin, “Selective IR multiphoton dissociation of molecules in a pulsed gas-dynamically cooled molecular flow interacting with a solid surface as an alternative to low-energy methods of molecular laser isotope separation”, Kvantovaya Elektronika, 46:3 (2016),  248–254  mathnet  elib [Quantum Electron., 46:3 (2016), 248–254  isi  scopus] 16
2015
19. G. N. Makarov, “Low energy methods of molecular laser isotope separation”, UFN, 185:7 (2015),  717–751  mathnet  elib; Phys. Usp., 58:7 (2015), 670–700  isi  elib  scopus 36
2013
20. V. M. Apatin, V. N. Lokhman, G. N. Makarov, N.-D. D. Ogurok, A. N. Petin, E. A. Ryabov, “Laser ultraviolet fragmentation of homogeneous (CF$_3$I)$_n$ clusters in a molecular beam and (CF$_3$I)$_n$ clusters inside of large (Xe)$_m$ clusters or on their surface”, Pis'ma v Zh. Èksper. Teoret. Fiz., 97:12 (2013),  800–806  mathnet  elib; JETP Letters, 97:12 (2013), 697–703  isi  elib  scopus 12
21. G. N. Makarov, A. N. Petin, “Disintegration of argon clusters in collisions with highly vibrationally excited SF$_6$ molecules in crossed molecular and cluster beams”, Pis'ma v Zh. Èksper. Teoret. Fiz., 97:2 (2013),  82–87  mathnet  elib; JETP Letters, 97:2 (2013), 76–81  isi  elib  scopus 16
22. G. N. Makarov, “Laser applications in nanotechnology: nanofabrication using laser ablation and laser nanolithography”, UFN, 183:7 (2013),  673–718  mathnet  elib; Phys. Usp., 56:7 (2013), 643–682  isi  elib  scopus 87
2011
23. G. N. Makarov, A. N. Petin, “Laser control of the capture of chromophore molecules by nanoclusters of noble gases in crossed molecular and cluster beams”, Pis'ma v Zh. Èksper. Teoret. Fiz., 93:3 (2011),  123–128  mathnet; JETP Letters, 93:3 (2011), 109–113  isi  scopus 17
24. G. N. Makarov, “Kinetic methods for measuring the temperature of clusters and nanoparticles in molecular beams”, UFN, 181:4 (2011),  365–387  mathnet; Phys. Usp., 54:4 (2011), 351–370  isi  scopus 17
2010
25. G. N. Makarov, “Experimental methods for determining the melting temperature and the heat of melting of clusters and nanoparticles”, UFN, 180:2 (2010),  185–207  mathnet; Phys. Usp., 53:2 (2010), 179–198  isi  scopus 50
2009
26. G. N. Makarov, A. N. Petin, “Universal probe method for measuring the temperature of large clusters (nanoparticles) in a cluster beam”, Pis'ma v Zh. Èksper. Teoret. Fiz., 90:10 (2009),  712–717  mathnet; JETP Letters, 90:10 (2009), 642–646  isi  scopus 8
27. G. N. Makarov, A. N. Petin, “Detection of SF$_6$ molecules sublimating from the surface of (CO$_2$)$_N$ nanoparticles in a cluster beam by the infrared multiphoton excitation method”, Pis'ma v Zh. Èksper. Teoret. Fiz., 89:8 (2009),  468–472  mathnet; JETP Letters, 89:8 (2009), 404–408  isi  scopus 6
28. G. N. Makarov, A. N. Petin, “IR multiphoton excitation of SF<sub>6</sub> molecules subliming from the surface of (CO<sub>2</sub>)<i><sub>N</sub></i> nanoparticles in a cluster beam”, Kvantovaya Elektronika, 39:11 (2009),  1054–1058  mathnet  elib [Quantum Electron., 39:11 (2009), 1054–1058  isi  scopus] 4
29. G. N. Makarov, “Cluster spectroscopy using high-intensity pulses from vacuum UV free electron lasers”, UFN, 179:5 (2009),  487–516  mathnet; Phys. Usp., 52:5 (2009), 461–486  isi  scopus 11
2008
30. G. N. Makarov, “Cluster temperature. Methods for its measurement and stabilization”, UFN, 178:4 (2008),  337–376  mathnet; Phys. Usp., 51:4 (2008), 319–353  isi  scopus 61
2006
31. G. N. Makarov, A. N. Petin, “Increase in the probability of passing molecules through a cooled multichannel plate as induced by a high-power infrared laser”, Pis'ma v Zh. Èksper. Teoret. Fiz., 83:3 (2006),  115–119  mathnet; JETP Letters, 83:3 (2006), 87–90  isi  scopus 7
32. G. N. Makarov, A. N. Petin, “Efficiency of passage of highly vibrationally excited CF<sub>3</sub>I molecules in a beam through a cooled converging hollow truncated cone”, Kvantovaya Elektronika, 36:9 (2006),  889–894  mathnet  elib [Quantum Electron., 36:9 (2006), 889–894  isi  scopus] 6
33. V. M. Apatin, A. N. Belokurov, G. N. Makarov, P. Mendoza, A. N. Petin, S. V. Pigulskii, I. Rios, E. A. Ryabov, “On the possibility of development of a photochemical unit based on an NH<sub>3</sub> laser with an intracavity reactor”, Kvantovaya Elektronika, 36:3 (2006),  292–298  mathnet  elib [Quantum Electron., 36:3 (2006), 292–298  isi  scopus]
34. G. N. Makarov, “On the possibility of selecting molecules embedded in superfluid helium nanodroplets (clusters)”, UFN, 176:11 (2006),  1155–1176  mathnet; Phys. Usp., 49:11 (2006), 1131–1150  isi  scopus 24
35. G. N. Makarov, “Extreme processes in clusters impacting on a solid surface”, UFN, 176:2 (2006),  121–174  mathnet; Phys. Usp., 49:2 (2006), 117–166  isi  scopus 51
2005
36. G. N. Makarov, “Selective processes of IR excitation and dissociation of molecules in gasdynamically cooled jets and flows”, UFN, 175:1 (2005),  41–84  mathnet; Phys. Usp., 48:1 (2005), 37–76  isi 50
2004
37. G. N. Makarov, “Spectroscopy of single molecules and clusters inside helium nanodroplets. Microscopic manifestation of ${}^4\mathrm{Νε}$ superfluidity”, UFN, 174:3 (2004),  225–257  mathnet; Phys. Usp., 47:3 (2004), 217–247  isi 42
2003
38. G. N. Makarov, “Studies on high-intensity pulsed molecular beams and flows interacting with a solid surface”, UFN, 173:9 (2003),  913–940  mathnet; Phys. Usp., 46:9 (2003), 889–914  isi 41
2002
39. G. N. Makarov, “Generating intense beams of low-energy molecules”, Pis'ma v Zh. Èksper. Teoret. Fiz., 76:5 (2002),  341–344  mathnet; JETP Letters, 76:5 (2002), 283–286  scopus 5
40. G. N. Makarov, “Pulse duration control for intense molecular beams”, Pis'ma v Zh. Èksper. Teoret. Fiz., 75:3 (2002),  159–169  mathnet; JETP Letters, 75:3 (2002), 131–134  scopus 1
2001
41. V. M. Apatin, G. N. Makarov, V. V. Nesterov, “Generation of high-energy secondary pulsed molecular beams”, Pis'ma v Zh. Èksper. Teoret. Fiz., 73:12 (2001),  735–739  mathnet; JETP Letters, 73:12 (2001), 651–654  scopus 4
42. G. N. Makarov, S. A. Mochalov, A. N. Petin, “Selective IR multiphoton dissociation of CF<sub>3</sub>I in a nonequilibrium pressure shock”, Kvantovaya Elektronika, 31:3 (2001),  263–267  mathnet [Quantum Electron., 31:3 (2001), 263–267  isi] 13
2000
43. G. N. Makarov, A. N. Petin, “Efficiency of selective IR multiphoton dissociation of molecules in a pulsed gas-dynamic flow interacting with a solid surface”, Kvantovaya Elektronika, 30:8 (2000),  738–740  mathnet [Quantum Electron., 30:8 (2000), 738–740  isi] 9
1998
44. G. N. Makarov, V. N. Lokhman, D. E. Malinovskii, D D. Ogurok, “Isotopically selective IR multiphoton dissociation of CF<sub>3</sub>I molecules in a pulsed gasdynamic flow”, Kvantovaya Elektronika, 25:6 (1998),  545–549  mathnet [Quantum Electron., 28:6 (1998), 530–534  isi] 19
1997
45. G. N. Makarov, N. D. Ogurok, A. N. Petin, “Generation of multiband tunable radiation in TEA CO<sub>2</sub> lasers”, Kvantovaya Elektronika, 24:7 (1997),  643–648  mathnet [Quantum Electron., 27:7 (1997), 626–630  isi]
1996
46. V. N. Lokhman, G. N. Makarov, E. A. Ryabov, M. V. Sotnikov, “Carbon isotope separation by infrared multiphoton dissociation of CF<sub>2</sub>HCl molecules with a separation reactor in a laser cavity”, Kvantovaya Elektronika, 23:1 (1996),  81–88  mathnet [Quantum Electron., 26:1 (1996), 79–86  isi] 10
1990
47. O. I. Davarashvili, A. V. Kunets, Yu. A. Kuritsyn, G. N. Makarov, V. R. Mironenko, I. Pak, A. P. Shotov, “Measurement of the emission line width of TEA CO<sub>2</sub> lasers using tunable diode lasers”, Kvantovaya Elektronika, 17:8 (1990),  1077–1080  mathnet [Sov J Quantum Electron, 20:8 (1990), 993–995  isi] 1
1989
48. Yu. A. Kuritsyn, G. N. Makarov, V. R. Mironenko, I. Pak, “Role of the mode composition of laser radiation in the case of pulsed infrared excitation of molecules”, Kvantovaya Elektronika, 16:8 (1989),  1664–1671  mathnet [Sov J Quantum Electron, 19:8 (1989), 1072–1076  isi] 1
1988
49. G. N. Makarov, M. V. Sotnikov, V. V. Tyakht, “Nonlinear absorption and generation of microwave radiation due to interaction of ammonia molecules with high-power infrared radiation”, Kvantovaya Elektronika, 15:8 (1988),  1577–1586  mathnet [Sov J Quantum Electron, 18:8 (1988), 985–990  isi]
1986
50. G. N. Makarov, “Dynamic tuning of the frequency of pulsed CO<sub>2</sub> lasers and the attainment of multispike lasing using an intracavity cell containing an infrared absorbing gas”, Kvantovaya Elektronika, 13:9 (1986),  1801–1807  mathnet [Sov J Quantum Electron, 16:9 (1986), 1184–1188  isi] 5
51. G. N. Makarov, “Control of the duration of CO<sub>2</sub> laser pulses by an intracavity infrared-absorbing gas cell”, Kvantovaya Elektronika, 13:8 (1986),  1665–1669  mathnet [Sov J Quantum Electron, 16:8 (1986), 1086–1089  isi] 2
1983
52. V. M. Apatin, G. N. Makarov, “Multiphoton infrared absorption in CF<sub>3</sub>I molecules cooled in a pulsed jet”, Kvantovaya Elektronika, 10:7 (1983),  1435–1441  mathnet [Sov J Quantum Electron, 13:7 (1983), 932–936  isi] 5
53. V. M. Apatin, G. N. Makarov, “Role of the intensity (duration) of excitation pulses in multiphoton infrared absorption and dissociation of SF<sub>6</sub> molecules”, Kvantovaya Elektronika, 10:7 (1983),  1308–1315  mathnet [Sov J Quantum Electron, 13:7 (1983), 847–851  isi] 4
1982
54. V. M. Apatin, G. N. Makarov, “Some characteristics of spectra of multiphoton absorption in SF<sub>6</sub> under conditions of essentially collisionless excitation of the molecules by CO<sub>2</sub> laser pulses”, Kvantovaya Elektronika, 9:8 (1982),  1668–1672  mathnet [Sov J Quantum Electron, 12:8 (1982), 1067–1070  isi] 10
1977
55. R. V. Ambartsumyan, Yu. A. Gorokhov, G. N. Makarov, A. A. Puretskiĭ, N. P. Furzikov, “Separation of osmium isotopes by dissociation of the OsO<sub>4</sub> molecule in a two-frequency infrared laser field”, Kvantovaya Elektronika, 4:7 (1977),  1590–1591  mathnet [Sov J Quantum Electron, 7:7 (1977), 904–905] 7
1976
56. R. V. Ambartsumyan, Yu. A. Gorokhov, V. S. Letokhov, G. N. Makarov, E. A. Ryabov, N. V. Chekalin, “Separation of isotopes in a strong infrared laser field”, Kvantovaya Elektronika, 3:4 (1976),  802–810  mathnet [Sov J Quantum Electron, 6:4 (1976), 437–441] 10
1975
57. R. V. Ambartsumyan, Yu. A. Gorokhov, V. S. Letokhov, G. N. Makarov, E. A. Ryabov, N. V. Chekalin, “Separation of B<sup>10</sup> and B<sup>11</sup> isotopes in a strong infrared CO<sub>2</sub> laser radiation field”, Kvantovaya Elektronika, 2:10 (1975),  2197–2201  mathnet [Sov J Quantum Electron, 5:10 (1975), 1196–1198] 12

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