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Publications in Math-Net.Ru |
Citations |
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2025 |
| 1. |
K. K. Maevskii, “Simulation of the behavior of on calcite under high-energy impact taking into account the phase transition”, Prikl. Mekh. Tekh. Fiz., 66:2 (2025), 55–62   ; J. Appl. Mech. Tech. Phys., 66:2 (2025), 225–232 |
| 2. |
K. K. Maevskii, “Numerical simulation of a high-energy impact on Al$_2$O$_3$”, Vestn. Tomsk. Gos. Univ. Mat. Mekh., 2025, no. 94, 163–174 |
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2024 |
| 3. |
K. K. Maevskii, “Modeling periclase behavior under high-energy impact”, Fizika Goreniya i Vzryva, 60:2 (2024), 127–135 ; Combustion, Explosion and Shock Waves, 60:2 (2024), 260–268 |
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2023 |
| 4. |
K. K. Maevskii, “Numerical simulation of the behavior of enstatite up to 1.4 TPa”, Fizika Tverdogo Tela, 65:6 (2023), 1071–1076 |
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2022 |
| 5. |
K. K. Maevskii, “Modeling of shock-wave loading of magnesium silicates on the example of forsterite”, Zhurnal Tekhnicheskoi Fiziki, 92:12 (2022), 1820–1826 |
| 6. |
K. K. Maevskii, “Numerical modeling of carbides behavior under high-energy loading”, Zhurnal Tekhnicheskoi Fiziki, 92:1 (2022), 100–107 |
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| 7. |
K. K. Maevskii, “Numerical simulation of the thermodynamic parameters of germanium”, TVT, 60:6 (2022), 837–843 ; High Temperature, 60:6 (2022), 768–774 |
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| 8. |
K. K. Maevskiy, “Magnesium silicates at high dynamic loading”, Vestn. Tomsk. Gos. Univ. Mat. Mekh., 2022, no. 79, 111–119 |
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2021 |
| 9. |
K. K. Maevskii, “Numerical study of shock-wave loading of the W- and WC-based metal composites”, Zhurnal Tekhnicheskoi Fiziki, 91:5 (2021), 815–820 ; Tech. Phys., 66:6 (2021), 749–754  |
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| 10. |
K. K. Maevskii, “Numerical simulation of thermodynamic parameters of carbon”, TVT, 59:5 (2021), 701–706 ; High Temperature, 60:1, Suppl. 2 (2022), S194–S199 |
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2019 |
| 11. |
K. K. Maevskii, S. A. Kinelovskii, “Numerical modeling of thermodynamic parameters of highly porous copper”, Zhurnal Tekhnicheskoi Fiziki, 89:8 (2019), 1158–1163 ; Tech. Phys., 64:8 (2019), 1090–1095 |
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| 12. |
K. K. Maevskii, S. A. Kinelovskii, “Modeling of high-porosity copper-based mixtures under shock loading”, Prikl. Mekh. Tekh. Fiz., 60:4 (2019), 26–34 ; J. Appl. Mech. Tech. Phys., 60:4 (2019), 612–619 |
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2018 |
| 13. |
K. K. Maevskii, S. A. Kinelovskii, “Thermodynamic parameters of mixtures with silicon nitride under shock-wave impact in terms of equilibrium model”, TVT, 56:6 (2018), 876–881 ; High Temperature, 56:6 (2018), 853–858  |
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2016 |
| 14. |
S. A. Kinelovskii, K. K. Maevskii, “Estimation of the thermodynamic parameters of a shock-wave action on high-porosity heterogeneous materials”, Zhurnal Tekhnicheskoi Fiziki, 86:8 (2016), 125–130 ; Tech. Phys., 61:8 (2016), 1244–1249 |
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| 15. |
S. A. Kinelovskii, K. K. Maevskii, “Modeling shock loading of multicomponent materials including bismuth”, TVT, 54:5 (2016), 716–723 ; High Temperature, 54:5 (2016), 675–681 |
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2014 |
| 16. |
S. A. Kinelovskii, K. K. Maevskiy, “Model of the behavior of aluminum and aluminum-based mixtures under shock-wave loading”, TVT, 52:6 (2014), 843–851 ; High Temperature, 52:6 (2014), 821–829 |
30
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| 17. |
S. A. Kinelovskii, K. K. Maevskii, “A behavior model for porous iron containing mixtures upon shock wave loading”, Vestn. Tomsk. Gos. Univ. Mat. Mekh., 2014, no. 3(29), 82–93 |
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2013 |
| 18. |
S. A. Kinelovskii, K. K. Maevskii, “Model of the behavior of the mixture with different properties of the species under high dynamic loads”, Prikl. Mekh. Tekh. Fiz., 54:4 (2013), 13–21 ; J. Appl. Mech. Tech. Phys., 54:4 (2013), 524–530 |
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2011 |
| 19. |
S. A. Kinelovskii, K. K. Maevskii, “Simple model for calculating shock adiabats of powder mixtures”, Fizika Goreniya i Vzryva, 47:6 (2011), 101–109 ; Combustion, Explosion and Shock Waves, 47:6 (2011), 706–714 |
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1989 |
| 20. |
S. A. Kinelovskii, K. K. Maevskii, “Penetration of a strong barrier by a shaped charge jet”, Prikl. Mekh. Tekh. Fiz., 30:2 (1989), 150–156 ; J. Appl. Mech. Tech. Phys., 30:2 (1989), 308–312 |
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