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V. V. Popov, I. I. Gorbachev & A. Yu. Pasynkov. (2016) Simulation of precipitates evolution in multiphase multicomponent systems with consideration of nucleation. Philosophical Magazine 96:35, pages 3632-3653.
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T. N. Baker. (2009) Processes, microstructure and properties of vanadium microalloyed steels. Materials Science and Technology 25:9, pages 1083-1107.
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S. F. Medina, P. Valles, J. Calvo & Jose M. Cabrera. (2020) Nucleation and Growth of Precipitates in a V-Microalloyed Steel According to Physical Theory and Experimental Results. Physics of Metals and Metallography 121:1, pages 32-40.
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V. N. Urtsev, V. L. Kornilov, A. V. Shmakov, M. L. Krasnov, P. A. Stekanov, S. I. Platov, E. D. Mokshin, N. V. Urtsev, V. M. Schastlivtsev, I. K. Razumov & Yu. N. Gornostyrev. (2020) Formation of the Structural State of a High-Strength Low-Alloy Steel upon Hot Rolling and Controlled Cooling. Physics of Metals and Metallography 120:12, pages 1233-1241.
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V. V. Popov & I. I. Gorbachev. (2019) Computer Simulation for the Prediction of Phase Composition and Structure of Low-Alloyed Steels with Carbonitride Hardening. Physics of Metals and Metallography 119:13, pages 1333-1337.
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I. I. Gorbachev, A. Yu. Pasynkov & V. V. Popov. (2018) Simulation of the Evolution of Carbonitride Particles of Complex Composition upon Hot Deformation of a Low-Alloyed Steel. Physics of Metals and Metallography 119:8, pages 770-779.
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I. I. Gorbachev, A. Yu. Pasynkov & V. V. Popov. (2018) Simulation of the Effect of Hot Deformation on the Austenite Grain Size of Low-Alloyed Steels with Carbonitride Hardening. Physics of Metals and Metallography 119:6, pages 551-557.
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I. I. Gorbachev, A. Yu. Pasynkov & V. V. Popov. (2015) Prediction of the austenite-grain size of microalloyed steels based on the simulation of the evolution of carbonitride precipitates. The Physics of Metals and Metallography 116:11, pages 1127-1134.
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I. I. Gorbachev, V. V. Popov & A. Yu. Pasynkov. (2015) Simulation of precipitate ensemble evolution in steels with V and Nb. The Physics of Metals and Metallography 116:4, pages 356-366.
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I.I. Gorbachev, Vladimir V. Popov & A.Yu. Pasynkov. (2015) Simulation of Precipitates Evolution in Steels with V and Nb at Annealing. Diffusion Foundations 3, pages 167-180.
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I. I. Gorbachev, V. V. Popov & A. Yu. Pasynkov. (2013) Simulation of evolution of precipitates of two carbonitride phases in Nb- and Ti-containing steels during isothermal annealing. The Physics of Metals and Metallography 114:9, pages 741-751.
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V. V. Popov. 2013. Industrial and Technological Applications of Transport in Porous Materials. Industrial and Technological Applications of Transport in Porous Materials
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Vladimir V. Popov & I. Gorbachev. (2007) Simulation of Precipitates Evolution in Steels. Defect and Diffusion Forum 263, pages 171-176.
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J. Svoboda, E. Gamsjäger & F.D. Fischer. (2006) Influence of diffusional stress relaxation on growth of stoichiometric precipitates in binary systems. Acta Materialia 54:17, pages 4575-4581.
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I. I. Gorbachev, V. V. Popov & E. N. Akimova. (2006) Computer simulation of the diffusion interaction between carbonitride precipitates and austenitic matrix with allowance for the possibility of variation of their composition. The Physics of Metals and Metallography 102:1, pages 18-28.
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V. V. Popov & I. I. Gorbachev. (2005) Numerical simulation of carbide and nitride precipitate evolution in steels. Materialwissenschaft und Werkstofftechnik 36:10, pages 477-481.
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