| References |
1. Olenin M. I., Gorynin V. I., Makhorin V. V. Increasing the cold resistance of 09G2S steel due to programmed hardening combined with additional medium-temperature tempering. Voprosy materialovedeniya. 2020. No. 1 (101). pp. 27-34. DOI: 10.22349/1994-6716-2019-100-4-27-34 2. Popov K. V., Savitsky V. G. Low-temperature brittleness of steel and machine parts. Moscow: Mashinostroenie, 1969. 192 p. 3. Makhutov N. A. Spectral acoustic emission analysis of the deformation and damage process. Zavodskaya laboratoriya. Diagnostika materialov. 2018. Vol. 84, No. 10. pp. 53-58. DOI: 10.26896/1028-6861-2018-84-10-53-58
4. Truell R., Elbaum C., Chick B. Ultrasonic methods in solid state physics. Translated from English. Moscow: Mir, 1972. 307 p. 5. Wang P., Zhang Y., YaoE. Method of measuring the mechanical properties of ferromagnetic materials based on magnetostrictive EMAT characteristic parameters. Measurement. 2021. Vol. 168. p. 108187. DOI: 10.1016/j.measurement.2020.108187 6. Guz A. N.,Makhort F. G. The physical fundamentals of the ultrasonic nondestructive stress analysis of solids. International Applied Mechanics. 2000. Vol. 36. No. 9. pp. 1119–1149. DOI: 10.1023/A:1009442132064 7. Muravyov V. V., Zuev L. B., Komarov K. L. Speed of sound and structure of steels and alloys. Novosibirsk: Nauka, 1996. 184 p. 8. Muravyov V. V., Muravyeva O. V., Bayteryakov A. V. Structural-sensitive acoustic parameters of structural steels. Izhevsk: Kalashnikov Izhevsk State Technical University, 2020. 152 p. 9. Sheng H., Wang P. Evaluation of pipeline steel mechanical property distribution based on multi-micromagnetic NDT method. IEEE Transactions on Instrumentation and Measurement. 2023. Vol. 72. p. 6001715. DOI: 10.1109/TIM.2023.3241060 10. Khlybov A. A., Uglov A. L. On the use of structural noise parameters in monitoring 20GL steel by Rayleigh surface acoustic waves during elastic-plastic deformation. Defektoskopiya. 2021. No. 7. pp. 3–10. DOI: 10.31857/S0130308221070010 11. Kowalczyk J., Jósko M., Wieczorek D., Sedłak, K., Nowak M. The influence of the hardness of the tested material and the surface preparation method on the results of ultrasonic testing. Applied Sciences. 2023. Vol. 13. No. 17. p. 9904. DOI: 10.3390/app13179904 12. Mishakin V. V., Gonchar A. V., Klyushnikov V. A., Kurashkin K. V. Study of the influence of plastic deformation on the crystallographic texture and ultrasonic characteristics of low-alloy steel. Problemy prochnosti i plastichnosti. 2021. Vol. 83, No. 3. pp. 255-264. DOI: 10.32326/1814-9146-2021-83-3-255-264 13. Berezin A. V., Kozinkina A. I., Rybakova L. M. Acoustic emission and destruction of plastically deformed metal. Defektoskopiya. 2004. No. 3. pp. 9–14. 14. Barannikova S. A., Bochkareva A. V., Lunev A. G., Shlyakhova G. V., Zuev L. B. Change in the speed of ultrasound during plastic deformation of high-chromium steel. Izvestiya vysshikh uchebnykh zavedeniy. Chernaya metallurgiya. 2016. Vol. 59, No. 8. pp. 558-564. DOI: 10.17073/0368-0797-2016-8-558-564 15. Carvajal L., Artigas A., Monsalve A., Arévalo E. Monitoring heat treatments in steels by a non-destructive ultrasonic method. Materials Research. 2017. Vol. 20(2). pp. 347–352. DOI: 10.1590/1980-5373-mr-2016-1083 16. Freitas V. L. A., Albuquerque V. H. C., Silva E. M., Silva A. A., Tavares J. M. R. S. Nondestructive characterization of microstructures and determination of elastic properties in plain carbon steel using ultrasonic measurements. Materials Science and Engineering A. 2010. Vol. 27 (16-17). pp. 4431–4437. DOI: 10.1016/j.msea.2010.03.090 17. Fujita M., Kuki K. An evaluation of mechanical properties with the hardness of building steel structural members for reuse by NDT. Metals. 2016. Vol. 6. p. 247. DOI: 10.3390/met6100247 18. Kumar A., Jayakumar T., Raj B., Ray K. K. Correlation between ultrasonic shear wave velocity and Poisson’s ratio for isotropic solid materials. Acta Materialia. 2003. Vol. 51. pp. 2417–2426. DOI: 10.1016/S1359-6454(03)00054-5 19. Hamidnia M., Honarvar F. Measurement of elastic properties of AISI 52100 alloy steel by ultrasonic nondestructive methods. Journal of Mechanics of Materials and Structures. 2013. Vol. 7 (10). pp. 951–961. DOI: 10.2140/jomms.2021.7.951 20. Pham T. V., Kien D. T. Influence of temperature on mechanical characteristics of 1018 low carbon steel estimated by ultrasonic non-destructive testing method. Indian Journal of Pure and Applied Physics. 2017. Vol. 55. pp. 431–435. 21. Muravyov V. V., Muravyeva O. V., Barannikova S. A. et al. Promising methods of structuroscopy and NDT of materials and articles. Izhevsk: Kalashnikov Izhevsk State Technical University, 2025. 300 p. 22. Fetisov V. P. Localization of plastic deformation during deformation of low-carbon steel. Lityo i metallurgiya. 2022. No. 4. pp. 51–54. DOI: 10.21122/1683-6065-2022-4-51-54 23. Terentyev V. F., Orlov L. G., Poyda V. G. Features of the plastic deformation behavior of bcc metals in the region of microflow. Problemy prochnosti. 1972. No. 9. pp. 34–37. 24. Nagarajan S., Narayanaswamy R., Balasubramaniam V. Study on local zones constituting to band growth associated with inhomogeneous plastic deformation. Materials Letters. 2013. Vol. 105. pp. 209–212. DOI: 10.1016/j.matlet.2013.04.014 25. Barannikova S. A., Nadezhkin M. V., Lunev A. G., Gorbatenko V. V., Shlyakhova G. V., Zuev L. B. Study of localized plastic flow in 08ps hot-rolled steel. Deformatsiya i razrushenie materialov. 2014. No. 4. pp. 34–39. 26. Danilov V. I.,Orlova D. V., Gorbatenko V. V., Zuev L. B. Kinetics and morphology of Lüders deformation in specimens with homogeneous structure and with a weld joint. Materials Science and Engineering: A. 2018. Vol. 714. pp. 160–166. DOI: 10.1016/j.msea.2017.12.100 27. Tipalin S. A., Gnevashev D. A., Borisov N. D., Bodnar M. V., Klimov V. A. Changes in the properties of 20 grade sheet steel depending on rolled products thickness. Chernye Metally. 2025. No. 12. pp. 79–83. 28. Ilyakhinsky A. V., Rodyushkin V. M., Ryabov D. A., Khlybov A. A., Erofeev V. I. Study of acoustic emission signals during 20 steel tensile testing. Problemy prochnosti i plastichnosti. 2021. Vol. 83. No. 2. pp. 188–197. 29. Karavaytseva A. A., Kveglis L. I., Gert S. S., Anfilofiev V. V. Absorption of ultrasound in 20GL manganese steel. Zhurnal Sibirskogo federalnogo universiteta. Seriya: Tekhnika i tekhnologii. 2019. Vol. 12, No. 3. pp. 356–365. DOI: 10.17516/1999-494X-0143 30. Novikov I. I., Roshchupkin V. V., Lyakhovitsky M. M. et al. Experimental study of the 20 steel acoustic properties. Opticheskiy zhurnal. 2014. Vol. 81. No. 6. pp. 79–84. 31. Zuev L. B., Semukhin B. S., Bushmeleva K. I. Ultrasound velocity in low-carbon steel deformed at the lower yield point. Prikladnaya mekhanika i tekhnicheskaya fizika. 2000. Vol. 41. No. 3. pp. 197-201. 32. Pelleg J . Mechanical Properties of Materials. Dordrecht: Springer, 2013. 634 p. 33. Zuev L. B., Khon Yu. A., Gorbatenko V. V. Physics of non-uniform plastic flow. Moscow: Fizmatlit, 2024. 316 p. 34. Shlyakhova G. V., Barannikova S. A., Zuev L. B. On the use of atomic force microscopy in metallography. Deformatsiya i razrushenie materialov. 2019. No. 1. pp. 32–36. DOI: 10.31044/1814-4632-2019-1-32-36 35. Caillard D., Martin J. L. Thermally Activated Mechanisms in Crystal Plasticity. Oxford: Elsevier, 2003. 433 p. 36. Suzuki T., Yoshinaga H., Takeuchi S. Dislocation dynamics and plasticity. Translated from Japan. Moscow: Mir, 1989. 294 p. 37. Petrov Yu. V., Borodin I. N. Relaxation mechanism of plastic deformation and its justification using the example of the phenomenon of yield drop in whiskers. FTT. 2015. Vol. 57, No. 2. pp. 336–341. 38. Ivanova V. S., Gordienko L. K., Geminov V. N. et al. The role of dislocations in the strengthening and destruction of metals. Moscow : Nauka, 1965. 180 p. 39. Farber V. M., Selivanova O. V., Morozova A. N., Khotinov V. A., Khadyev M. S., Zhilyakov A. Yu. Dislocation structure in the localized deformation band formed during tension of a normalized sample of 09G2S steel. Fizicheskaya mezomekhanika. 2023. Vol. 26, No. 5. pp. 53–60. DOI: 10.55652/1683-805X_2023_26_5_53 40. Maurel A., Pagneux V., Barra F., Lund F. Wave propagation through a random array of pinned dislocations: velocity change and attenuation in a generalized Granato and Lücke theory. Physical Review B. 2005. Vol. 72. p. 174111. DOI: 10.1103/PhysRevB.72.174111 |