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Publications in Math-Net.Ru |
Citations |
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2021 |
1. |
V. Yu. Gidaspov, M. D. Zyong, N. S. Severina, “Numerical stduy of the effect of gas nonideality on shock wave focusing in a channel with a hemispherical end”, TVT, 59:5 (2021), 730–736 ; High Temperature, 60:1, Suppl. 2 (2022), S223–S229 |
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2020 |
2. |
V. Yu. Gidaspov, D. S. Kononov, N. S. Severina, “Simulation of the ignition and detonation of methane–air mixtures behind a reflected shock wave”, TVT, 58:6 (2020), 909–914 ; High Temperature, 58:6 (2020), 846–851 |
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2019 |
3. |
V. Yu. Gidaspov, N. S. Severina, “Modeling of detonation of metal-gas combustible mixtures in high-speed flow behind a shock wave”, TVT, 57:4 (2019), 560–571 ; High Temperature, 57:4 (2019), 514–524 |
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2018 |
4. |
V. Yu. Gidaspov, O. A. Moskalenko, N. S. Severina, “Numerical study of the influence of water droplets on the structure of a detonation wave in a hydrogen–air fuel mixture”, TVT, 56:5 (2018), 782–788 ; High Temperature, 56:5 (2018), 751–757 |
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2017 |
5. |
V. Yu. Gidaspov, N. S. Severina, “Numeric simulation of the detonation of a propane-air mixture, taking irreversible chemical reactions into account”, TVT, 55:5 (2017), 795–799 ; High Temperature, 55:5 (2017), 777–781 |
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2016 |
6. |
V. Yu. Gidaspov, V. K. Golubev, N. S. Severina, “A software package for simulation of unsteady flows of the reacting gas in the channel”, Vestnik YuUrGU. Ser. Mat. Model. Progr., 9:3 (2016), 94–104 |
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2015 |
7. |
V. Yu. Gidaspov, N. S. Severina, “Numerical simulation of the fine structure of a cylindrical detonation wave in a hydrogen–air combustible mixture”, TVT, 53:4 (2015), 556–560 ; High Temperature, 53:4 (2015), 526–530 |
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2013 |
8. |
V. Yu. Gidaspov, N. S. Severina, “Numerical simulation of experiments to determine ignition delays behind incident shock wave”, Fizika Goreniya i Vzryva, 49:4 (2013), 31–40 ; Combustion, Explosion and Shock Waves, 49:4 (2013), 409–417 |
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2009 |
9. |
V. Ju. Gidaspov, S. A. Losev, N. S. Severina, “The nonequilibrium kinetics on the oxygen dissociation behind shock wave front”, Matem. Mod., 21:9 (2009), 3–15 ; Math. Models Comput. Simul., 2:2 (2010), 211–221 |
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Organisations |
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