Issue 41

E. Tolmacheva (Lyapunova) et alii, Frattura ed Integrità Strutturale, 41 (2017) 552-561; DOI: 10.3221/IGF-ESIS.41.65 561 R EFERENCES [1] Subhash, G., Maiti, S., Geubelle, P.H., Ghosh, D., Recent advances in dynamic indentation fracture, impact damage and fragmentation of ceramics. Journal of American ceramic society, 91 (2008) 2777-2791. [2] Ghosh, D., Subhash, G., Bourne, G.R., Inelastic deformation under indentation and scratch loads in ZrB2-SiC composite. Journal of European ceramic society, 9 (2009) 3053-4061. [3] Ghosh, D., Subhash, G., Sudatshan, T.S., Radhakrishnan, R., Gao, X.-L., Dynamic indentation response of fine- grained boron carbide. Journal of American ceramic society, 90(6) (2007) 1850-1857. [4] LaSalvia, J.C., McCauley, J.W., Inelastic deformation mechanisms and damage in structural ceramics subjected to high velocity impact. International journal of applied ceramic technology, 7(5) (2010) 595-605. [5] Klecka, M.A., Subhash, G., Rate-dependent indentation of structural ceramics. Journal of American society, 93(8) (2010) 2377-2383. [6] Al-Mousawi, M.M., Reid, S.R., Deans, W.F., The use of the split Hopkinson pressure bar techniques in high strain rate materials testing. Proceedings of the institution of mechanical engineers, 211C (1997) 273-292. [7] Bragov, A.M., Lomunov, A.K., Methodological aspects of studying dynamic material properties using the Kolsky method. International journal of impact engineering, 16 (1995) 321–330. [8] Bragov, A.M., Demenko, P.V., Lomunov, A.K., Sergeichev, I.V., Kruszka, L., Investigation of behaviour of materials of different physical nature using the Kolsky method and its modifications. New experimental methods in material dynamics and impact, trends in mechanics of materials, eds. Nowacki W.K., Klepaczko J.R., Warsaw, (2001) 337–348. [9] Sokovikov, M., Chudinov, V., Bilalov, D., Oborin, V., Uvarov, S. , Plekhov, O. , Naimark, O., Study of plastic strain localization mechanisms caused by nonequilibrium transitions in mesodefect ensembles under high-speed loading. AIP Conference Proceedings, 1683 (2015) 020218. [10] Bilalov, D.A., Sokovikov, M.A., Chudinov, V.A., Oborin, V.A., Bayandin, Yu.V., Terekhina, A.I., Naimark, O.B. Studying plastic shear localization in aluminum alloys under dynamic loading. Journal of applied mechanics and technical physics, 57(7) (2016) 1217-1225. [11] Abramoff, M.D., Magalhaes, P.J., Ram, S.J., Image processing with ImageJ. Biophotonics international, 11(7) (2004) 36–42. [12] Schneider, C.A., Rasband, W.S., Eliceiri, K.W., NIH image to ImageJ: 25 years of image analysis, Nature methods. 9(7) (2012) 671. [13] Zukas, J.A., Impact dynamic, Wiley, (1982) 452. [14] He, L.H., Swain, M.V., Nanoindentation derived stress-strain properties of dental materials, Dental materials, 23 (2007) 814-821. [15] Xu, H.H.K., Smith, D.T., Jahanmir, S., Romberg, E., Kelly, J.R., Thompson, V.P., Rekow, E.D., Indentation damage and mechanical properties of human enamel and dentin, Journal of dental research, 77 (1998) 472-480. [16] Zhang, Y.-R., Du, W., Zhou, X.-D., Yu, H.-Y., Review of research on the mechanical properties of human tooth, International journal of oral science, 6 (2014) 61-69.