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Publications in Math-Net.Ru |
Citations |
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2022 |
1. |
A. S. Abramov, I. O. Zolotovskii, A. S. Kadochkin, S. G. Moiseev, I. S. Panyaev, D. G. Sannikov, M. S. Yavtushenko, V. V. Svetukhin, A. A. Fotiadi, “Generation of frequency-modulated optical IR pulses in a semiconductor waveguide structure with a realised space charge wave”, Kvantovaya Elektronika, 52:11 (2022), 1044–1049 [Bull. Lebedev Physics Institute, 50:suppl. 3 (2023), S374–S382] |
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2021 |
2. |
S. V. Bulyarskii, D. A. Koiva, G. G. Gusarov, V. V. Svetukhin, “Changes in the titanium oxide optical properties during crystallization”, Optics and Spectroscopy, 129:11 (2021), 1426–1434 ; Optics and Spectroscopy, 130:14 (2022), 2148–2155 |
3. |
S. A. Afanas'ev, I. O. Zolotovskii, A. S. Kadochkin, S. G. Moiseev, V. V. Svetukhin, A. A. Pavlov, “Interwave interaction in an array of carbon nanotubes with a dynamic plasmon lattice”, Kvantovaya Elektronika, 51:7 (2021), 609–614 [Quantum Electron., 51:7 (2021), 609–614 ] |
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2020 |
4. |
D. A. Korobko, I. O. Zolotovskii, V. V. Svetukhin, A. V. Zhukov, A. N. Fomin, K. V. Borisova, A. A. Fotiadi, “Effect of frequency detuning on Brillouin lasing in microcavities”, Kvantovaya Elektronika, 50:3 (2020), 284–290 [Quantum Electron., 50:3 (2020), 284–290 ] |
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2019 |
5. |
P. E. L'vov, V. V. Svetukhin, S. V. Bulyarskii, “Modeling of nucleation in binary alloys on the basis of the free-energy density functional”, Fizika Tverdogo Tela, 61:12 (2019), 2415–2420 ; Phys. Solid State, 61:12 (2019), 2425–2430 |
6. |
P. E. L'vov, V. V. Svetukhin, S. V. Bulyarskii, A. A. Pavlov, “Simulation of wetting phase transitions in thin films”, Fizika Tverdogo Tela, 61:10 (2019), 1916–1925 ; Phys. Solid State, 61:10 (2019), 1872–1881 |
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7. |
P. E. L’vov, V. V. Svetukhin, “Effect of fluctuations on the formation of secondary phase precipitates at grain boundaries”, Fizika Tverdogo Tela, 61:2 (2019), 357–364 ; Phys. Solid State, 61:2 (2019), 225–232 |
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8. |
B. B. Kostishko, V. V. Svetukhin, I. O. Yavtushenko, “Research of the effect of different factors on the structuring of metals by femtosecond laser pulses”, University proceedings. Volga region. Physical and mathematical sciences, 2019, no. 1, 105–114 |
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2018 |
9. |
P. E. L'vov, V. V. Svetukhin, “Precipitation kinetics in binary alloys near grain boundaries”, Fizika Tverdogo Tela, 60:4 (2018), 787–794 ; Phys. Solid State, 60:4 (2018), 791–798 |
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10. |
S. A. Afanas'ev, I. O. Zolotovskii, A. S. Kadochkin, S. G. Moiseev, V. V. Svetukhin, A. A. Pavlov, “Continuous-wave laser generation of THz slow surface plasmons in an array of single-walled carbon nanotubes”, Kvantovaya Elektronika, 48:9 (2018), 849–853 [Quantum Electron., 48:9 (2018), 849–853 ] |
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2017 |
11. |
P. E. L'vov, V. V. Svetukhin, “Influence of grain boundaries on the distribution of components in binary alloys”, Fizika Tverdogo Tela, 59:12 (2017), 2425–2434 ; Phys. Solid State, 59:12 (2017), 2453–2463 |
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12. |
V. M. Zhuravlev, I. O. Zolotovskii, D. A. Korobko, V. M. Morozov, V. V. Svetukhin, I. O. Yavtushenko, M. S. Yavtushenko, “Laser-induced generation of surface periodic structures in media with nonlinear diffusion”, Fizika Tverdogo Tela, 59:12 (2017), 2291–2298 ; Phys. Solid State, 59:12 (2017), 2313–2320 |
13. |
P. E. L'vov, V. V. Svetukhin, “Simulation of the decomposition of binary alloys on the basis of the free energy density functional method”, Fizika Tverdogo Tela, 59:2 (2017), 345–350 ; Phys. Solid State, 59:2 (2017), 355–361 |
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14. |
S. V. Bulyarskii, A. V. Lakalin, I. E. Abanin, V. V. Amelichev, V. V. Svetukhin, “Optimization of the parameters of power sources excited by $\beta$-radiation”, Fizika i Tekhnika Poluprovodnikov, 51:1 (2017), 68–74 ; Semiconductors, 51:1 (2017), 66–72 |
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15. |
M. Yu. Tikhonchev, V. V. Svetukhin, “Threshold energies of atomic displacements in $\alpha$-Fe under deformation: Molecular dynamics simulation”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 43:7 (2017), 56–62 ; Tech. Phys. Lett., 43:4 (2017), 348–350 |
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2016 |
16. |
P. E. L'vov, V. V. Svetukhin, “Simulation of the early stage of binary alloy decomposition, based on the free energy density functional method”, Fizika Tverdogo Tela, 58:7 (2016), 1382–1389 ; Phys. Solid State, 58:7 (2016), 1432–1439 |
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17. |
P. E. Kapustin, V. V. Svetukhin, M. Yu. Tikhonchev, “Primary radiation damage of the Zr-NB binary alloy: molecular dynamics modeling”, University proceedings. Volga region. Physical and mathematical sciences, 2016, no. 3, 133–144 |
18. |
P. E. Kapustin, V. V. Svetukhin, M. Yu. Tikhonchev, “Simulation of atomic displacement cascades in the deformed HCP zirconium model by the molecular dynamics method. Evaluation of the effect of deformation on the defect structure”, University proceedings. Volga region. Physical and mathematical sciences, 2016, no. 3, 115–132 |
19. |
P. E. L'vov, V. V. Svetukhin, K. S. Maslov, “Modeling of phase decomposition of supersaturated solid solutions using the free-energy density functional method”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 42:16 (2016), 56–63 |
3
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20. |
A. V. Faustov, A. I. Gusarov, P. Mégret, M. Wuilpart, D. Kinet, A. V. Zhukov, S. G. Novikov, V. V. Svetukhin, A. A. Fotiadi, “Gamma radiation-induced blue shift of resonance peaks of Bragg gratings in pure silica fibres”, Kvantovaya Elektronika, 46:2 (2016), 150–154 [Quantum Electron., 46:2 (2016), 150–154 ] |
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2015 |
21. |
P. E. Kapustin, V. V. Svetukhin, M. Yu. Tikhonchev, “Atomic displacement cascades near symmetrical tilt grain boundaries in HCP Zr: molecular dynamics simulation”, University proceedings. Volga region. Physical and mathematical sciences, 2015, no. 2, 148–163 |
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22. |
R. T. Sibatov, V. V. Svetukhin, “Subdiffusion kinetics of nanoprecipitate growth and destruction in solid solutions”, TMF, 183:3 (2015), 460–476 ; Theoret. and Math. Phys., 183:3 (2015), 846–859 |
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2014 |
23. |
M. Yu. Tikhonchev, A. B. Muralev, V. V. Svetukhin, “Energy properties of twin grain boundaries in the FeCr alloy: molecular statics simulation”, University proceedings. Volga region. Physical and mathematical sciences, 2014, no. 2, 73–87 |
24. |
A. B. Muralev, M. Yu. Tikhonchev, V. V. Svetukhin, “Molecular-dynamic simulation of atomic displacement cascades in FeCr alloy”, University proceedings. Volga region. Physical and mathematical sciences, 2014, no. 1, 156–166 |
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2013 |
25. |
M. Yu. Makhmud-Akhunov, M. Yu. Tikhonchev, V. V. Svetukhin, “Simulation of phase transformations of uranium dioxide by molecular dynamics method”, University proceedings. Volga region. Physical and mathematical sciences, 2013, no. 3, 199–211 |
26. |
E. S. Pchelintseva, S. G. Novikov, A. V. Berintsev, B. M. Kostishko, V. V. Svetukhin, “Modeling of a pulse radiation-induced power source”, University proceedings. Volga region. Physical and mathematical sciences, 2013, no. 2, 147–155 |
27. |
A. B. Muralev, M. Yu. Tikhonchev, V. V. Svetukhin, “Modeling the cascades of atomic displacements in alpha iron containing simmetrically tilt grain boundary”, University proceedings. Volga region. Physical and mathematical sciences, 2013, no. 1, 144–158 |
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2012 |
28. |
V. V. Svetukhin, M. Yu. Tikhonchev, “Simulation of the interaction of atomic displacement cascades with chromium-enriched precipitates in the FeCr alloy”, University proceedings. Volga region. Physical and mathematical sciences, 2012, no. 4, 162–173 |
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2010 |
29. |
I. Nagornov, R. Yu. Makhmud-Akhunov, M. Yu. Tikhonchev, B. M. Kostishko, V. N. Golovanov, V. V. Svetukhin, “Construction of a temperature-dependent interparticle interaction potential for uranium dioxide”, University proceedings. Volga region. Physical and mathematical sciences, 2010, no. 3, 156–164 |
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30. |
M. Yu. Tikhonchev, V. V. Svetukhin, V. N. Golovanov, D. V. Kozlov, “Modeling of the processes of primary radiation damage of the alloy Fe-1.8at.%Ni by the method of molecular dynamics”, University proceedings. Volga region. Physical and mathematical sciences, 2010, no. 3, 143–155 |
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