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Publications in Math-Net.Ru |
Citations |
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2024 |
1. |
Спектральная зависимость оптической плотности среды в УФ и видимой области при образовании сажи и полиароматических углеводородов при пиролизе углеводородов
TVT, Forthcoming paper |
2. |
О режимах распространении волны саморазложения ацетилена в ударно-нагретых потоках в трубах малых диаметров
TVT, Forthcoming paper |
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2023 |
3. |
A. V. Drakon, A.V. V. Eremin, M. R. Korshunova, E. Yu. Mikheyeva, “Ignition of multicomponent combustible mixtures behind shock waves in the presence of trifluoroiodomethane”, Fizika Goreniya i Vzryva, 59:3 (2023), 74–83 ; Combustion, Explosion and Shock Waves, 59:3 (2023), 321–329 |
4. |
A. V. Drakon, A. V. Eremin, V. N. Zolotarenko, M. R. Korshunova, E. Yu. Mikheyeva, “Experimental investigation of the formation of polyaromatic hydrocarbons and soot during pyrolysis of ethylene with additives of dimethyl, diethyl ether, and dimethoxymethane”, Fizika Goreniya i Vzryva, 59:2 (2023), 69–82 ; Combustion, Explosion and Shock Waves, 59:2 (2023), 185–198 |
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2022 |
5. |
A. V. Drakon, A. V. Eremin, M. R. Korshunova, E. Yu. Mikheyeva, “Soot formation in ethylene pyrolysis with furan and tetrahydrofuran additives”, Fizika Goreniya i Vzryva, 58:4 (2022), 41–51 ; Combustion, Explosion and Shock Waves, 58:4 (2022), 430–439 |
6. |
E. V. Gurentsov, A. V. Drakon, A.V. Eremin, E. Yu. Mikheeva, “On the effect of a small acetone impurity on the thermal self-decomposition of acetylene”, TVT, 60:6 (2022), 897–905 ; High Temperature, 60:6 (2022), 830–837 |
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7. |
E. V. Gurentsov, A. V. Drakon, A. V. Eremin, R. N. Kolotushkin, E. Yu. Mikheyeva, “Effect of the size and structure of soot particles synthesized during pyrolysis and combustion of hydrocarbons on their optical properties”, TVT, 60:3 (2022), 374–384 ; High Temperature, 60:3 (2022), 335–344 |
2
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2021 |
8. |
A. V. Eremin, “Различные механизмы инициирования детонации – «вечнозеленая тема» академика Фортова”, TVT, 59:6 (2021), 903–924 |
1
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9. |
A.V. Eremin, V. E. Fortov, “Detonation wave of condensation”, UFN, 191:11 (2021), 1131–1152 ; Phys. Usp., 64:11 (2021), 1073–1093 |
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2019 |
10. |
A. V. Eremin, M. R. Korshunova, E. Yu. Mikheyeva, “On the effect of combustion inhibitors on the level of non-equilibrium radiation during ignition of hydrogen oxygen mixtures behind a shock wave”, Fizika Goreniya i Vzryva, 55:1 (2019), 136–139 ; Combustion, Explosion and Shock Waves, 55:1 (2019), 121–124 |
3
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11. |
E. V. Gurentsov, A.V. Eremin, S. A. Musikhin, “Study of evaporation of laser-heated iron–carbon nanoparticles using analysis of thermal radiation”, Zhurnal Tekhnicheskoi Fiziki, 89:8 (2019), 1200–1207 ; Tech. Phys., 64:8 (2019), 1133–1139 |
4
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2017 |
12. |
A. V. Emelianov, A. V. Eremin, P. I. Yatsenko, “Experimental study of chlorine atom interaction with acetylene behind shock waves”, TVT, 55:5 (2017), 806–812 ; High Temperature, 55:5 (2017), 788–794 |
2
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13. |
E. V. Gurentsov, A. V. Eremin, E. Yu. Mikheeva, “Study of thermodynamic properties of carbon nanoparticles by the laser heating method”, TVT, 55:5 (2017), 737–745 ; High Temperature, 55:5 (2017), 723–730 |
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14. |
A. V. Drakon, A. V. Emelianov, A. V. Eremin, P. I. Yatsenko, “Study of trifluoromethane within wide pressure and temperature ranges by molecular resonance absorption spectroscopy”, TVT, 55:2 (2017), 247–254 ; High Temperature, 55:2 (2017), 239–245 |
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2016 |
15. |
A. V. Drakon, A. V. Eremin, O. P. Korobeinichev, V. M. Shvartsberg, A. G. Shmakov, “Promoting effect of halogenand phosphorus-containing flame retardants on the autoignition of a methane-oxygen mixture”, Fizika Goreniya i Vzryva, 52:4 (2016), 3–14 ; Combustion, Explosion and Shock Waves, 52:4 (2016), 375–385 |
9
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16. |
E. V. Gurentsov, A. V. Eremin, E. Yu. Mikheeva, S. A. Musikhin, “Anomalous behavior of optical density of iron nanoparticles heated behind shock waves”, TVT, 54:6 (2016), 960–962 ; High Temperature, 54:6 (2016), 902–904 |
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2015 |
17. |
V. V. Golub, E. V. Gurentsov, A. V. Emelianov, A. V. Eremin, V. E. Fortov, “Energy gain of the detonation pyrolysis of acetylene”, TVT, 53:3 (2015), 383–389 ; High Temperature, 53:3 (2015), 363–369 |
12
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2013 |
18. |
A. V. Eremin, “A new model for carbon nanoparticle formation in the pyrolysis process behind shock waves”, TVT, 51:5 (2013), 747–754 ; High Temperature, 51:5 (2013), 673–680 |
11
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2012 |
19. |
S. Ya. Bronin, A. V. Emelianov, A. V. Eremin, A. G. Khrapak, “The effect of chlorine atoms on the charging kinetics of carbon nanoparticles forming in shock-heated plasma”, TVT, 50:6 (2012), 739–745 ; High Temperature, 50:6 (2012), 687–693 |
3
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2011 |
20. |
A. V. Emelianov, A. V. Eremin, Yu. V. Petrushevich, E. E. Sivkova, A. N. Starostin, M. D. Taran, V. E. Fortov, “Quantum effects in the kinetics of the initiation of detonation condensation waves”, Pis'ma v Zh. Èksper. Teoret. Fiz., 94:7 (2011), 570–575 ; JETP Letters, 94:7 (2011), 530–534 |
10
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21. |
E. V. Gurentsov, A. V. Eremin, “Size Measurement of Carbon and Iron Nanoparticles by Laser Induced Incadescence”, TVT, 49:5 (2011), 687–694 ; High Temperature, 49:5 (2011), 667–673 |
30
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22. |
S. Ya. Bronin, A. V. Emelianov, A. V. Eremin, A. G. Khrapak, “Investigation of the Kinetics of Carbon Nanoparticle Charging in Shock-Heated Plasma ъ”, TVT, 49:3 (2011), 357–364 ; High Temperature, 49:3 (2011), 349–355 |
4
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2010 |
23. |
A. V. Emelianov, A. V. Eremin, A. A. Makeich, V. E. Fortov, “Formation of detonation wave upon condensation of supersaturated carbon vapor”, TVT, 48:6 (2010), 862–868 ; High Temperature, 48:6 (2010), 823–829 |
4
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2008 |
24. |
A. V. Emelianov, A. V. Eremin, A. A. Makeich, V. E. Fortov, “Formation of a detonation-like condensation wave”, Pis'ma v Zh. Èksper. Teoret. Fiz., 87:9 (2008), 556–559 ; JETP Letters, 87:9 (2008), 470–473 |
12
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2002 |
25. |
E. V. Gurentsov, O. G. Divakov, A. V. Eremin, “Ignition of Multicomponent Hydrocarbon/Air Mixtures behind Shock Waves”, TVT, 40:3 (2002), 416–423 ; High Temperature, 40:3 (2002), 379–386 |
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2000 |
26. |
L. B. Ibragimova, G. D. Smekhov, O. P. Shatalov, A. V. Eremin, V. V. Shumova, “Dissociation of $\mathrm{CO}_2$ molecules in a wide temperature range”, TVT, 38:1 (2000), 37–40 ; High Temperature, 38:1 (2000), 33–36 |
9
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1993 |
27. |
A.V. Eremin, V. S. Ziborov, “Recombination radiation from a nonequilibrium jet of dissociated carbon dioxide”, Prikl. Mekh. Tekh. Fiz., 34:6 (1993), 10–20 ; J. Appl. Mech. Tech. Phys., 34:6 (1993), 752–760 |
3
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1991 |
28. |
A. V. Emelianov, A.V. Eremin, “Generalized empirical laws of starting discontinuity dynamics associated with the startup of underexpanded jets”, Prikl. Mekh. Tekh. Fiz., 32:5 (1991), 22–26 ; J. Appl. Mech. Tech. Phys., 32:5 (1991), 665–669 |
2
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1990 |
29. |
A.V. Eremin, I. M. Naboko, “Density distribution in pulsed gas jets effusing into a rarefied space”, Prikl. Mekh. Tekh. Fiz., 31:6 (1990), 123–127 ; J. Appl. Mech. Tech. Phys., 31:6 (1990), 914–918 |
30. |
A.V. Eremin, V. S. Ziborov, “An experimental study into the nonsteady radiation of a jet consisting of an impact-heating gas containing CO$_2$”, Prikl. Mekh. Tekh. Fiz., 31:4 (1990), 31–38 ; J. Appl. Mech. Tech. Phys., 31:4 (1990), 533–540 |
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1978 |
31. |
A.V. Eremin, V. A. Kochnev, A. A. Kulikovskii, I. M. Naboko, “Nonstationary processes in starting strongly underexpanded jets”, Prikl. Mekh. Tekh. Fiz., 19:1 (1978), 34–40 ; J. Appl. Mech. Tech. Phys., 19:1 (1978), 27–31 |
7
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1976 |
32. |
A. V. Eremin, V. A. Kochnev, A. A. Kulikovskii, I. M. Naboko, “Экспериментальное определение полного рабочего времени в ударной трубе (№ 2481 Деп. от 1 VII 1976)”, TVT, 14:4 (1976), 915–916 |
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1975 |
33. |
A.V. Eremin, V. A. Kochnev, I. M. Naboko, “Formation of a jet of gas outflowing into evacuated space”, Prikl. Mekh. Tekh. Fiz., 16:2 (1975), 53–58 ; J. Appl. Mech. Tech. Phys., 16:2 (1975), 196–200 |
2
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2010 |
34. |
A. V. Emelianov, A. V. Eremin, V. E. Fortov, “Formation of a detonation wave in the thermal decomposition of acetylene”, Pis'ma v Zh. Èksper. Teoret. Fiz., 92:2 (2010), 101–105 ; JETP Letters, 92:2 (2010), 97–101 |
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