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Publications in Math-Net.Ru |
Citations |
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2022 |
1. |
A. M. Molodets, A. A. Golyshev, G. V. Shilov, “Physicochemical transformations of boron carbide at high temperatures and high pressures of shock compression”, TVT, 60:2 (2022), 208–212 ; High Temperature, 60:2 (2022), 182–186 |
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2021 |
2. |
A. M. Molodets, A. A. Golyshev, “The volume–temperature dependence of electrical and thermophysical properties of $\alpha$ iron under high pressures and temperatures”, Zhurnal Tekhnicheskoi Fiziki, 91:9 (2021), 1403–1408 ; Tech. Phys., 66:11 (2021), 1247–1252 |
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3. |
A. M. Molodets, A. A. Golyshev, A. N. Emel'yanov, A. A. Kozlov, “Magnetic transformations and polymorphic transition of ferromagnetic steels under shock-wave loading”, Zhurnal Tekhnicheskoi Fiziki, 91:5 (2021), 803–807 ; Tech. Phys., 66:6 (2021), 755–759 |
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2020 |
4. |
A. M. Molodets, A. A. Golyshev, D. V. Shakhrai, D. Yu. Kovalev, “Spall strength of shock-heated zirconium and phase diagram of its high-pressure polymorphic modification”, Fizika Tverdogo Tela, 62:1 (2020), 59–68 ; Phys. Solid State, 62:1 (2020), 65–73 |
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5. |
A. M. Molodets, A. A. Golyshev, G. V. Shilov, “Melting of shocked boron carbide”, Pis'ma v Zh. Èksper. Teoret. Fiz., 111:12 (2020), 838–845 ; JETP Letters, 111:12 (2020), 720–726 |
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2019 |
6. |
A. M. Molodets, A. A. Golyshev, “Spall strength of shock-heated hafnium and the equations of state of its polymorphic modifications”, Fizika Tverdogo Tela, 61:8 (2019), 1492–1498 ; Phys. Solid State, 61:8 (2019), 1437–1443 |
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7. |
A. M. Molodets, A. S. Savinykh, A. A. Golyshev, “Spall strength of amorphous carbon (glassy carbon) under shock loading in the region of its anomalous compressibility”, Pis'ma v Zh. Èksper. Teoret. Fiz., 109:7 (2019), 460–465 ; JETP Letters, 109:7 (2019), 449–453 |
8. |
A. M. Molodets, A. S. Savinykh, A. A. Golyshev, G. V. Garkushin, “The spall strength and dynamic yield stress of hafnium”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 45:2 (2019), 29–32 ; Tech. Phys. Lett., 45:1 (2019), 27–30 |
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2018 |
9. |
A. M. Molodets, A. A. Golyshev, “Amorphization and a polymorphic transformation of boron stimulated by high dynamic pressures”, Pis'ma v Zh. Èksper. Teoret. Fiz., 108:6 (2018), 430–434 ; JETP Letters, 108:6 (2018), 409–413 |
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2017 |
10. |
A. M. Molodets, A. A. Golyshev, D. V. Shakhrai, V. V. Kim, “Electrical conductivity and equations of states of $\beta$-rhombohedral boron in the megabar dynamic pressure range”, Fizika Tverdogo Tela, 59:7 (2017), 1379–1386 ; Phys. Solid State, 59:7 (2017), 1406–1413 |
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11. |
A. M. Molodets, D. V. Shakhrai, A. A. Golyshev, “Semiempirical description of thermophysical properties of lithium deuteride at high pressures and temperatures”, TVT, 55:4 (2017), 523–527 ; High Temperature, 55:4 (2017), 510–514 |
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2016 |
12. |
Yu. R. Kolobov, S. S. Manokhin, A. Yu. Kolobova, Yu. E. Kudymova, V. I. Betekhtin, A. A. Golyshev, A. M. Molodets, R. A. Andrievski, “Shock-wave-induced grain refinement and phase state modification in coarse-grained and nanocrystalline titanium”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 42:18 (2016), 63–71 ; Tech. Phys. Lett., 42:9 (2016), 959–962 |
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2015 |
13. |
A. A. Golyshev, V. V. Kim, A. N. Emel'yanov, A. M. Molodets, “Model for calculating shock-compression parameters of a platelet gradient mixture”, Prikl. Mekh. Tekh. Fiz., 56:4 (2015), 92–100 ; J. Appl. Mech. Tech. Phys., 56:4 (2015), 618–625 |
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2014 |
14. |
A. M. Molodets, A. A. Golyshev, A. N. Emel'yanov, Yu. M. Shul'ga, V. E. Fortov, “Jump in the electrical conductivity of shock-compressed glassy carbon”, Pis'ma v Zh. Èksper. Teoret. Fiz., 99:4 (2014), 263–267 ; JETP Letters, 99:4 (2014), 237–241 |
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2013 |
15. |
A. M. Molodets, D. V. Shakhrai, A. S. Savinykh, A. A. Golyshev, V. V. Kim, “Equation of state of polytetrafluoroethylene for calculating shock compression parameters at megabar pressures”, Fizika Goreniya i Vzryva, 49:6 (2013), 121–129 ; Combustion, Explosion and Shock Waves, 49:6 (2013), 731–738 |
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16. |
A. A. Golyshev, A. M. Molodets, “Electrical resistivity of plastic insulation at megabar shock pressures”, Fizika Goreniya i Vzryva, 49:2 (2013), 106–112 ; Combustion, Explosion and Shock Waves, 49:2 (2013), 219–224 |
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Organisations |
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