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Publications in Math-Net.Ru |
Citations |
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2024 |
1. |
I. S. Menshov, “Free boundary method for coupled problems of gas–solid dynamics”, Zh. Vychisl. Mat. Mat. Fiz., 64:8 (2024), 1546–1560 ; Comput. Math. Math. Phys., 64:8 (2024), 1809–1822 |
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2023 |
2. |
L. Wang, I. S. Menshov, A. A. Serezhkin, “Numerical and analytical investigation of shock wave processes in elastoplastic media”, Zh. Vychisl. Mat. Mat. Fiz., 63:10 (2023), 1660–1673 ; Comput. Math. Math. Phys., 63:10 (2023), 1860–1873 |
1
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2022 |
3. |
M. Y. Nemtsev, I. S. Menshov, I. V. Semenov, “Numerical simulation of dynamic processes in the medium of fine-grained solid particles”, Matem. Mod., 34:8 (2022), 73–96 ; Math. Models Comput. Simul., 15:2 (2023), 210–226 |
2
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4. |
A. V. Severin, A. E. Lutsky, I. S. Menshov, “High-speed channel flow control with porous inserts”, Matem. Mod., 34:4 (2022), 100–112 ; Math. Models Comput. Simul., 14:6 (2022), 937–945 |
4
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5. |
I. S. Menshov, A. A. Serezhkin, “Numerical model of multiphase flows based on sub-cell resolution of fluid interfaces”, Zh. Vychisl. Mat. Mat. Fiz., 62:10 (2022), 1740–1760 ; Comput. Math. Math. Phys., 62:10 (2022), 1723–1742 |
5
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2020 |
6. |
I. S. Menshov, “Generalized and variational statements of the Riemann problem with applications to the development of Godunov's method”, Zh. Vychisl. Mat. Mat. Fiz., 60:4 (2020), 663–675 ; Comput. Math. Math. Phys., 60:4 (2020), 651–662 |
3
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7. |
I. S. Menshov, Ch. Zhang, “Interface capturing method based on the Cahn–Hilliard equation for two-phase flows”, Zh. Vychisl. Mat. Mat. Fiz., 60:3 (2020), 476–488 ; Comput. Math. Math. Phys., 60:3 (2020), 472–483 |
4
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2019 |
8. |
A. L. Afendikov, A. E. Lutsky, I. S. Menshov, V. S. Nikitin, Ya. V. Khankhasaeva, “Numerical simulation of recirculation flow during supersonic separation of moving bodies”, Matem. Mod., 31:9 (2019), 21–38 ; Math. Models Comput. Simul., 12:3 (2020), 282–292 |
4
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9. |
Ch. Zhang, I. S. Menshov, “Continuous method for calculating the transport equations for a multicomponent heterogeneous system on fixed Euler grids”, Matem. Mod., 31:4 (2019), 111–130 ; Math. Models Comput. Simul., 11:6 (2019), 973–987 |
3
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10. |
I. S. Menshov, M. Yu. Nemtsev, I. V. Semenov, “Numerical modeling of wave processes accompanying combustion of inhomogeneously distributed composite propellant”, Zh. Vychisl. Mat. Mat. Fiz., 59:9 (2019), 1591–1604 ; Comput. Math. Math. Phys., 59:9 (2019), 1528–1541 |
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2018 |
11. |
R. S. Solomatin, I. V. Semenov, I. S. Menshov, “Towards calculating turbulent flows with the Spalart–Allmaras model by using the LU-SGS-GMRES algorithm”, Keldysh Institute preprints, 2018, 119, 30 pp. |
7
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2017 |
12. |
I. V. Semenov, I. S. Menshov, M. Yu. Nemtsev, “Mathematical modeling of the axisymmetric internal ballistics processes”, Keldysh Institute preprints, 2017, 143, 20 pp. |
13. |
V. E. Borisov, A. V. Ivanov, B. V. Kritsky, I. S. Men'shov, E. B. Savenkov, “Numerical simulation of poroelasticity problems”, Keldysh Institute preprints, 2017, 081, 36 pp. |
4
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14. |
Ch. Zhang, I. S. Menshov, “Numerical modeling of nature gas leakage from underwater gas pipeline”, Keldysh Institute preprints, 2017, 074, 18 pp. |
2
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15. |
A. V. Karakin, M. M. Ramazanov, V. E. Borisov, I. S. Men'shov, E. B. Savenkov, “Self-similar solution of hydraulic fracture problem for poroelastic medium”, Matem. Mod., 29:4 (2017), 59–74 ; Math. Models Comput. Simul., 9:6 (2017), 657–668 |
2
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16. |
K. E. Gorodnichev, P. P. Zakharov, S. E. Kuratov, I. S. Menshov, A. A. Serezhkin, “Disturbance evolution in the shock impact of a density non-uniform medium”, Matem. Mod., 29:3 (2017), 95–112 |
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2016 |
17. |
I. S. Menshov, V. S. Nikitin, V. V. Sheverdin, “Parallel three-dimensional LAD model on Cartesian grids of nested structure”, Keldysh Institute preprints, 2016, 118, 32 pp. |
18. |
Igor Menshov, “Exact and approximate Riemann solvers for compressible two-phase flows”, Matem. Mod., 28:12 (2016), 33–55 ; Math. Models Comput. Simul., 9:4 (2017), 405–422 |
4
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19. |
A. E. Lutsky, I. S. Menshov, Ya. V. Khankhasaeva, “Numerical simulation of the wake influence on the flow around truncated cone”, Matem. Mod., 28:7 (2016), 45–55 ; Math. Models Comput. Simul., 9:1 (2017), 92–100 |
3
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20. |
I. S. Menshov, P. V. Pavlukhin, “Efficient parallel shock-capturing method for aerodynamics simulations on body-unfitted Cartesian grids”, Zh. Vychisl. Mat. Mat. Fiz., 56:9 (2016), 1677–1691 ; Comput. Math. Math. Phys., 56:9 (2016), 1651–1664 |
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2015 |
21. |
A. L. Afendikov, A. A. Davydov, I. S. Menshov, K. D. Merkulov, A. V. Plenkin, “Algorithm for multilevel mesh adaptation with waveled-based criteria for gas dynamic problems”, Keldysh Institute preprints, 2015, 097, 22 pp. |
3
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22. |
A. L. Afendikov, A. E. Lutsky, I. S. Menshov, K. D. Merkulov, A. V. Plenkin, Ya. V. Khankhasaeva, “Algorithm of local mesh adaptation based on wavelet analysis with the use of free boundary method”, Keldysh Institute preprints, 2015, 094, 20 pp. |
3
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23. |
A. E. Lutsky, I. S. Menshov, A. V. Severin, “Estimation of typical frequencies of pressure pulsations in a flow over a rectangular cavity”, Keldysh Institute preprints, 2015, 080, 24 pp. |
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2014 |
24. |
A. E. Lutsky, I. S. Menshov, Ya. V. Khankhasaeva, “The use of free boundary method for solving the problem of the flow past moving bodies”, Keldysh Institute preprints, 2014, 093, 16 pp. |
1
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25. |
I. S. Menshov, P. V. Pavlukhin, “Numerical solution of gas dynamics problems on Cartesian grids with the use of hybrid computing systems”, Keldysh Institute preprints, 2014, 092, 24 pp. |
3
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26. |
V. E. Borisov, A. A. Davydov, I. Yu. Kudryashov, A. E. Lutsky, I. S. Men'shov, “Parallel implicit scheme implementation LU-SGS method for 3D turbulent flows”, Matem. Mod., 26:10 (2014), 64–78 ; Math. Models Comput. Simul., 7:3 (2015), 222–232 |
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27. |
I. Menshov, M. Kornev, “Free boundary method for numerical solving gas dynamics equations in domains with varying geometry”, Matem. Mod., 26:5 (2014), 99–112 ; Math. Models Comput. Simul., 6:6 (2014), 612–621 |
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2013 |
28. |
I. V. Semenov, P. A. Pasynkov, P. S. Utkin, I. F. Akhmedyanov, I. S. Menshov, “Численное моделирование внутрибаллистического процесса и околодульных течений на многопроцессорных ЭВМ”, Gorenie i vzryv, 6 (2013), 109–111 |
29. |
Igor Menshov, Alexander Mischenko, Alexey Serejkin, “Numerical modeling elasto-plastic flows by using a Godunov method with moving Eulerian grids”, Matem. Mod., 25:8 (2013), 89–108 ; Math. Models Comput. Simul., 6:2 (2014), 127–141 |
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2011 |
30. |
I. S. Menshov, A. N. Nenashev, “Modeling of large vortical structures in axisymmetrical jet flows”, Matem. Mod., 23:11 (2011), 111–130 |
1
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31. |
A. I. Ilyushin, A. A. Kolmakov, I. S. Menshov, “Constructing parallel numerical model by means of the composition of computational objects”, Matem. Mod., 23:7 (2011), 97–113 ; Math. Models Comput. Simul., 4:1 (2012), 118–128 |
1
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32. |
I. V. Semenov, P. S. Utkin, I. F. Akhmedyanov, I. S. Menshov, “Application of high performance computing to the solution of interior
ballistics problems”, Num. Meth. Prog., 12:1 (2011), 183–193 |
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2010 |
33. |
V. M. Fomin, V. I. Zapryagaev, A. V. Lokotko, V. F. Volkov, A. E. Lutsky, I. S. Menshov, Yu. M. Maksimov, A. I. Kirdyashkin, “Aerodynamic characteristics of a body of revolution with gas-permeable surface areas”, Prikl. Mekh. Tekh. Fiz., 51:1 (2010), 79–88 ; J. Appl. Mech. Tech. Phys., 51:1 (2010), 65–73 |
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2007 |
34. |
I. S. Menshov, “ethods of the variational Riemann problem in computational gasdynamics”, Matem. Mod., 19:6 (2007), 86–108 |
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1992 |
35. |
I. S. Menshov, “Increasing the accuracy of the Godunov scheme for calculating stationary supersonic gas flows based on the solution of the generalized Riemann problem”, Zh. Vychisl. Mat. Mat. Fiz., 32:2 (1992), 311–319 ; Comput. Math. Math. Phys., 32:2 (1992), 257–263 |
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1990 |
36. |
I. S. Menshov, “Increasing the order of approximation of Godunov's scheme using solutions of the generalized Riemann problem”, Zh. Vychisl. Mat. Mat. Fiz., 30:9 (1990), 1357–1371 ; U.S.S.R. Comput. Math. Math. Phys., 30:5 (1990), 54–65 |
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1989 |
37. |
V. P. Korobeinikov, V. V. Markov, L. I. Sedov, I. S. Menshov, “On the non-homogeneity of density fields behind shock propagating through dust-gas mixture”, Trudy Mat. Inst. Steklov., 186 (1989), 70–73 ; Proc. Steklov Inst. Math., 186 (1991), 81–84 |
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1987 |
38. |
L. I. Sedov, B. N. Epifantsev, V. P. Korobeinikov, A. M. Lapidus, V. V. Markov, I. S. Menshov, G. G. Tivanov, K. N. Shamshev, “The formation of high-concentration particle zone behind a shock
wave in a two-phase medium”, Dokl. Akad. Nauk SSSR, 296:6 (1987), 1327–1330 |
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1986 |
39. |
V. P. Korobeinikov, V. V. Markov, I. S. Menshov, “Numerical modeling of shock wave propagation in nonuniform dust-gas mixture”, Dokl. Akad. Nauk SSSR, 290:4 (1986), 816–819 |
2
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1984 |
40. |
V. P. Korobeinikov, V. V. Markov, I. S. Menshov, “The problem of a strong blast in a dust-filled gas”, Trudy Mat. Inst. Steklov., 163 (1984), 104–107 ; Proc. Steklov Inst. Math., 163 (1985), 125–128 |
1
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1983 |
41. |
V. P. Korobeinikov, I. S. Menshov, “Filtration of a liquid with a free boundary in nonideal porous
media with the nonlinear resistance law”, Dokl. Akad. Nauk SSSR, 268:5 (1983), 1078–1081 |
2
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1982 |
42. |
I. S. Menshov, “Propagation of strong detonation waves in a dispersed mixture”, Dokl. Akad. Nauk SSSR, 267:4 (1982), 808–811 |
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Presentations in Math-Net.Ru |
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