OBRABOTKAMETALLOV Vol. 27 No. 2 2025 267 MATERIAL SCIENCE 4. Shuitcev A.V., Ren Y., Gunderov D.V., Vasin R.N., Li L., Valiev R.Z., Zheng Y.F., Tong Y.X. Grain growth in Ni50Ti30Hf20 high-temperature shape memory alloy processed by high-pressure torsion. Materials Science and Engineering: A, 2024, vol. 918, p. 147478. DOI: 10.1016/j.msea.2024.147478. 5. Andreev V.A., Yusupov V.S., Perkas M.M., Yakushevich N.V. Goryachaya rotatsionnaya kovka prutkov diametrom 2–20 mm iz splavov s pamyat’yu formy na osnove nikelida titana [Hot rotary forging of bars with a diameter of 2–20 mm from shape memory alloys based on titanium nickelide]. Perspektivnye materialy i tekhnologii. V 2 t. T. 1 [Promising materials and technologies. In 2 vol. Vol. 1]. Vitebsk, Vitebsk State Technological University Publ., 2017, pp. 61–69. 6. Andreev V.A., Karelin R.D., Komarov V.S. Cherkasov V.V., Dormidontov N.A., Laisheva N.V., Yusupov V.S. Vliyanie rezhimov rotatsionnoi kovki i posledeformatsionnoi termicheskoi obrabotki na mekhanicheskie i funktsional’nye svoistva nikelida titana [Infl uence of rotary forging and post-deformation heat treatment on mechanical and functional properties of titanium nickelide]. Metallurg = Metallurgist, 2023, no. 12, pp. 87–92. DOI: 10.52351/00260827_2023_12_87. (In Russian). 7. LotkovA.I., GrishkovV.N., BaturinA.A., Dudarev E.F., ZhapovaD.Yu., TimkinV.N. Vliyanie teploi deformatsii metodom abc-pressovaniya na mekhanicheskie svoistva nikelida titana [The eff ect of warm deformation by abcpressing method on mechanical properties of titanium nickelide]. Pis’ma o materialakh = Letters on Materials, 2015, vol. 5 (2), pp. 170–174. DOI: 10.22226/2410-3535-2015-2-170–174. (In Russian). 8. Fedotkin A.A., Stolyarov V.V. Osobennosti deformatsionnogo povedeniya nanostrukturnykh titanovykh splavov pri rastyazhenii pod deistviem impul’snogo toka [Features of the deformation behavior of nanostructured titanium alloys under tension under the action of pulsed current]. Mashinostroenie i inzhenernoe obrazovanie = Mechanical Engineering and Engineering Education, 2012, no. 1 (30), pp. 28–35. 9. Misochenko A.A., Fedotkin A.A., Stolyarov V.V. Infl uence of grain size and electric current regimes on deformation behavior under tension of shape memory alloy TI49,3NI50,7. Materials Today: Proceedings, 2017, vol. 4 (3), pp. 4753–4757. DOI: 10.1016/j.matpr.2017.04.065. 10. Stolyarov V.V. Elektroplasticheskii eff ekt v krupnozernistom i ul’tramelkozernistom titane [The electroplastic eff ect in coarse-grained and ultrafi ne-grained titanium]. Zavodskaya laboratoriya. Diagnostika materialov = Industrial laboratory. Diagnostics of materials, 2023, vol. 89 (8), pp. 62–66. DOI: 10.26896/1028-6861-2023-89-862-66. (In Russian). 11. Khalik M.A., Zahiri S.H., Masood S.H., Palanisamy S., Guliz S. In situ electro-plastic treatment for thermomechanical processing of CP titanium. The International Journal of Advanced Manufacturing Technology, 2021, vol. 115, pp. 2639–2657. DOI: 10.1007/s00170-021-07342-6. 12. Baranov Yu.V., Troitskii O.A., Avraamov Yu.S., Shlyapin A.D. Fizicheskie osnovy elektroimpul’snoi i elektroplasticheskoi obrabotok i novye materialy [Physical foundations of electric pulse and electroplastic treatments and new materials]. Moscow, MSIU Publ., 2001. 844 p. 13. Jiang B., Yang W., Zhang Z., Li X., Ren X., Wang Y. Numerical simulation and experiment of electricallyassisted incremental forming of thin TC4 titanium alloy sheet. Materials, 2020, vol. 13 (6), p. 1335. DOI: 10.3390/ ma13061335. 14. Xu Z., Jiang T., Huang J., Peng L., Lai X., Fu M.W. Electroplasticity in electrically-assisted forming: process phenomena, performances and modelling. International Journal of Machine Tools and Manufacture, 2022, vol. 175, p. 103871. DOI: 10.1016/j.ijmachtools.2022.103871. 15. Dobras D., Zimniak Z., Zwierzchowski M. Electrically-assisted deep drawing of 5754 aluminum alloy sheet. Materials Research Proceedings, 2023, vol. 28, pp. 987–1006. DOI: 10.21741/9781644902479-109. 16. Herbst S., Karsten E., Gerstein G., Reschka S., Nürnberger F., Zaeff erer S., Maier H.J. Electroplasticity mechanisms in hcp materials. Advanced Engineering Materials, 2023, vol. 25, p. 2201912. DOI: 10.1002/ adem.202201912. 17. Rudolf C., Goswami R., Kang W., Thomas J. Eff ects of electric current on the plastic deformation behavior of pure copper, iron, and titanium. Acta Materialia, 2021, vol. 209, p. 116776. DOI: 10.1016/j.actamat.2021.116776. 18. Stolyarov V., Calliari I., Gennari C. Features of the interaction of plastic deformation and pulse current in various materials. Materials Letters, 2021, vol. 299, p. 130049. DOI: 10.1016/j.matlet.2021.130049. 19. Potapova A.A., Stolyarov V.V. Deformability and structural features of shape memory TiNi alloys processed by rolling with current. Materials Science and Engineering: A, 2013, vol. 579, pp. 114–117. DOI: 10.1016/j. msea.2013.05.003. 20. Stolyarov V.V., Andreev V.A., Karelin R.D., Ugurchiev U.Kh., Cherkasov V.V., Komarov V.S., Yusupov V.S. Deformability of TiNiHf shape memory alloy under rolling with pulsed current. Obrabotka metallov (tekhnologiya,
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