References
- Deribas AA. Physics of strengthening and welding by explosion. Nauka: Novosibirsk; 1980.
- Lancaster JF. Metallurgy of welding. 6th ed. Abington, Cambridge: Abington Publishing; 1999. p. 446.
- Greenberg BA, et al. Structure of the melted zones during explosion welding (aluminum–tantalum, copper–titanium). Svarochnoe Proizvodstvo. 2016;5:25–35.
- Greenberg BA, Ivanov MA, Inozemtsev AV, et al. Interface relief upon explosion welding: splashes and waves. Phys Met Metall. 2015;4:367–377.
- Greenberg BA, Ivanov MA, Inozemtsev AV, et al. Evolution of interface relief during explosive welding. Bull Russ Acad Sci Phys. 2015;79:1118–1121.
- Greenberg BA, et al. The processes of self-organization and evolution of the interface during welding explosion (copper–tantalum, copper–titanium). Fundamental’nye problemy sovremennogo materialovedeniya. 2015;12:391–402.
- Lysak VI, Kuzmin SV. Explosion welding. Moscow: Mashinostroenie-1; 2005.
- Lysak VI, Kuzmin SV. Lower boundary in metal explosive welding. Evolution of ideas. J Mater Process Technol. 2012;212:150–156.
- Greenberg BA, Ivanov MA, Inozemtsev AV, et al. Microheterogeneous structure of local melted zones in the process of explosive welding. Metall Mater Trans A. 2015;8:3569–3580.
- Rybin VV, et al. The structure of the transition zone during explosion welding (titanium–orthorhombic titanium aluminide). Svarka i diagnostika. 2010;3:26–31.
- Rybin VV, et al. The formation of vortices during explosion welding (titanium–orthorhombic titanium aluminide). Fiz Met Metalloved. 2009;4:371–384.