Surface and bulk nanostructuring of titanium alloys

The work was supported by RFBR grant №16-58-48001. The author expresses his gratitude to Grand Ph. D. in E. S. Lesyuk E.A. and Petrzhik M.I., respectively, for assistance in conducting ultrasonic measurements and smoothing of anotherdate.

Publication date

15.12.2018

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GOST	Stolyarov V. Surface and bulk nanostructuring of titanium alloys // Problemy mashinostroeniia i nadezhnosti mashin – 2018. – Issue 6 C. 66-72 [Electronic resource]. URL: http://ras.jes.su/pminm/s207987840001738-0-1-en (circulation date: 20.04.2024). DOI: 10.31857/S023571190002563-0
MLA	Stolyarov, V. "Surface and bulk nanostructuring of titanium alloys." Problemy mashinostroeniia i nadezhnosti mashin 6 (2018):66-72. DOI: 10.31857/S023571190002563-0
APA	Stolyarov V. (2018). Surface and bulk nanostructuring of titanium alloys. Problemy mashinostroeniia i nadezhnosti mashin (6), pp.66-72 DOI: 10.31857/S023571190002563-0

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1. Valiev R.Z., Aleksandrov I.V. Ob'emnye nanostrukturnye metallicheskie materialy: poluchenie, struktura i svojstva. M.: IKTs «Akademkniga». 2007. 398 s.

2. Edalati K., Horita Z. A review on high-pressure torsion (HPT) from 1935 to 1988, MSE A652. 2016. P. 325–352.

3. Golovin Yu.I. M.: Vvedenie v nanotekhniku, M.: Mashinostroenie, 2007. 496 s.

4. Wua X., Jiang P., Chena L., Yuan F., Zhu Y.T. Extraordinary strain hardening by gradient structure, PNAS, May 20. 2014. V. 111. No. 20. P. 7197–7201.

5. Beygelzimer Y., Estrin Y., Kulagin R., Synthesis of Hybrid Materials by Severe Plastic Deformation: A New Paradigm of SPD Processing, Adv. Eng. Mater. 2015, 17 DOI: 10.1002/adem.201500083.

6. Wang Y., Molotnikov A., Diez M., Lapovok R., Kim H., Wang J., Estrin Y., Gradient structure produced by three roll planetary milling: Numerical simulation and microstructural observations, MSE, A639. 2015. P. 165–172.

7. Yurchenko L.I., Dyupin A.P., Gunderov D.V., Valiev R.Z. i dr. Mekhanicheskie svojstva i struktura vysokoprochnykh nanostrukturirovannykh splavov nikelida titana, podvergnutykh RKUP i prokatke. Fazovye perekhody, uporyadochennye sostoyaniya i novye materialy. Ehlektronnyj zhurnal. 2006. №10.

8. Kolobov Y.R., Manokhina S.S., Kolobova A. Yu. et al, Shock-Wave-Induced Grain Refinement and Phase State Modification in Coarse-Grained and Nanocrystalline Titanium, Technical Physics Letters. 2016. V. 42. № 9. P. 959–962.

9. Stolyarov V.V., Ugurchiev U.Kh., Trubitsyna I.B. i dr. Intensivnaya ehlektroplasticheskaya deformatsiya splava TiNi. FTVD. 2006. № 4. S. 48–51.

10. Stolyarov V.V. Deformability and nanostructuring of shape memory TiNi alloys during the electroplastic rolling. MSE. A503.2009. P. 18–20.

11. Lesyuk E.A., Alekhin V.P. Formirovanie nano- i submikrokristallicheskikh struktur v instrumental'nykh i konstruktsionnykh materialakh i obespechenie ikh termicheskoj stabil'nosti: monografiya. M.: MGIU. 2009. 247 s.

12. Mordyuk B., Prokopenko G., Ultrasonic impact peening for the surface properties’ management, Journal of Sound and Vibration. 308. 2007. P. 855–866.

13. Astashev V.K., Krupenin V.L. Nelinejnaya dinamika ul'trazvukovykh tekhnologicheskikh protsessov. M.: MGUP imeni Ivana Fedorova, 2016. 372 s.

14. Klimenov V.A., Kovalevska Zh.G., Uvarkin P.V. i dr. Ul'trazvukovoe modifitsirovanie poverkhnosti i ego vliyanie na svojstva pokrytij. Fizicheskaya mezomekhanika. 2004. T. 7. Spetsial'nyj vypusk, ch. 2. S. 157–160.

15. Lotkov A.I., Baturin A.A., Grishkov V.N. i dr. Defekty struktury i mezorel'ef poverkhnosti nikelida titana posle intensivnoj plasticheskoj deformatsii ul'trazvukovym metodom. Fizicheskaya mezomekhanika. 8. 2005. 109–112.

16. Shape Memory Alloys: Fundamentals, Modeling and Applications, in book ed. By V. Brailovski, S. Prokoshkin, P. Terriault and F. Trochu, ETS, Université du Québec, Montreal, 2003, 844p.

17. Cismasiu C., Shape Memory Alloys. SCIYO. Croatia. 2010. 218 r.