Issue 48

O. Plekhov et alii, Frattura ed Integrità Strutturale, 48 (2019) 451-458; DOI: 10.3221/IGF-ESIS.48.43 458 A CKNOWLEDGEMENTS his work was supported by the Russian Foundation for Basic Research (Grant No. 16-51-48003). R EFERENCES [1] Matvienko, Yu.G., Morozov, E M. (2004). Calculation of the energy J-integral for bodies with notches and cracks, International Journal of Fracture, 125, pp. 249-261. [2] Rosakis, P., Rosakis, A.J., Ravichandran, G., Hodowany, J. (2000). A thermodynamic internal variable model for the partitional of plastic work into heat and stored energy in metals, J. Mech. Phys. Solids, 48, pp. 581-607. [3] Oliferuk, W., Maj, M., Raniecki, B. (2004). Experimental analysis of energy storage rate components during tensile deformation of polycrystals, Materials Science and Engineering, 374, pp. 77-81. [4] Izyumova, A., Plekhov, O. (2014). Calculation of the energy J-integral in plastic zone ahead of a crack tip by infrared scanning, FFEMS, 37, pp. 1330–1337. [5] Meneghetti, G., Ricotta, M. (2016). Evaluating the heat energy dissipated in a small volume surrounding the tip of a fatigue crack, International Journal of Fatigue, 92(2), pp. 605-615. [6] Risitano, A., Risitano, G. (2013). Cumulative damage evaluation in multiple cycle fatigue tests taking into account energy parameter, International Journal of Fatigue, 48, pp. 214-222. [7] Ranganathan, N., Chalon, F., Meo, S. (2008). Some aspects of the energy based approach to fatigue crack propagation, International Journal of Fatigue, 30(10–11), pp. 1921-1929. [8] Bär, U., Vshivkov, A., Plekhov, O. (2015). Combined lock-in thermography and heat flow measurements for analysing heat dissipation during fatigue crack propagation, Fracture and structural integrity, 34, pp. 521-530. [9] Vshivkov, А., Iziumova, A., Bär, U., Plekhov, O. (2016). Experimental study of heat dissipation at the crack tip during fatigue crack propagation, Frattura ed Integrità Strutturale, 35, pp. 131-137. [10] Raju, K. N. (1972). An energy balance criterion for crack growth under fatigue loading from considerations of energy of plastic deformation, International Journal of Fracture Mechanics, 8(1), pp. 1-14. [11] Bär, U. (2016). Determination of dissipated energy in fatigue crack propagation experiments with lock-in thermography and heat flow measurement, Procedia Structural Integrity, 2, pp. 2105-2112. [12] Dixon, J.R. (1965). Stress and strain distributions around cracks in sheet materials having various work-hardening characteristics, Ministry of Technology, National Engineering Laboratory, Materials Group: East Kilbride, Glasgow, Scotland, pp. 224-244. T