Abstract
High-cycle and very-high-cycle fatigue is the most important fundamental and engineering problem for a variety of applications. Series of accidents caused by the gas turbine engine failure (Cowles, Int J Fract 80:147–163, 1996; Shanyavsky, Simulation of fatigue fracture of metals. Synergetics in aviation. Monografiya, Ufa, 2007), along with high costs of service life estimation and potential costs of development of new constructions, stimulated advanced concepts of national programs for high-cycle and very-high-cycle fatigue (Bathias and Paris, Gigacycle fatigue in mechanical practice. Dekker Publisher Co., Marcel, 2005; Botvina, Fracture: kinetics, mechanisms, general laws. Nauka, Moscow, 2008; Hong et al., Metall Mater Trans A 43(8):2753–2762, 2012; Mughrabi, Int J Fatigue 28:1501–1508, 2006; Nicolas, Int J Fatigue 21:221–231, 1999; Nicholas, High cycle fatigue. A mechanics of material perspective. Elsevier, Oxford, 2006; Paris et al., Eng Fract Mech 75:299–305, 2008; Peters and Ritchie, Eng Fract Mech 67:193–207, 2000; Sakai, J Solid Mech Mater Eng 3(3):425–439, 2009; Shanyavsky, Simulation of fatigue fracture of metals. Synergetics in aviation. Monografiya, Ufa, 2007), as being based on new fundamental results of fatigue evaluation. The programs aim at developing approaches using basic research findings, modern methods of laboratory modeling, and quantitative analysis of structural changes in order to reveal fracture stages and “criticality” mechanisms in transition to macroscopic fracture. A strong interest in the gigacycle range (109 cycles) of fatigue loads is provided by the progress in the creation of new (nano- and submicrostructural) materials with a very-high-cycle fatigue life and by breakthrough tendencies in technologies requiring such life in aviation motor industry (Nicolas, Int J Fatigue 21:221–231, 1999).
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References
Abaimov, S.G.: Statistical Physics of Non-thermal Phase Transitions (From Foundations to Applications). Series in Synergetics. Springer, Cham (2015)
Bannikov, M., Oborin, V., Naimark, O.: Experimental study of crack initiation and propagation in high- and gigacycle fatigue in titanium alloys. AIP Conf. Proc. 1623, 55 (2014)
Bannikov, M.V., Naimark, O.B., Oborin, V.A.: Experimental investigation of crack initiation and propagation in high- and gigacycle fatigue in titanium alloys by study of morphology of fracture. Frattura ed Integrità Strutturale 35, 50–56 (2016)
Barenblatt, G.I.: Scaling phenomena in fatigue and fracture. Int. J. Fract. 138, 19–35 (2006)
Bathias, C., Paris, P.C.: Gigacycle Fatigue in Mechanical Practice. Dekker Publisher Co., Marcel (2005)
Botvina, L.R.: Fracture: Kinetics, Mechanisms, General Laws. Nauka, Moscow (2008)
Bouchaud, E.: Scaling Properties of Cracks. J. Phys. Condens. Matter. 9, 4319–4344 (1997)
Ciavarella, M., Paggi, M., Carpinteri, A.: One, no one, and one hundred thousand crack propagation laws: a generalized Barenblatt and Botvina dimensional analysis approach to fatigue crack growth. J. Mech. Phys. Solids 56, 3416–3432 (2008)
Cowles, B.A.: High cycle fatigue in aircraft gas turbines—an industry perspective. Int. J. Fract. 80, 147–163 (1996)
Froustey, C., Naimark, O., Bannikov, M., Oborin, V.: Microstructure scaling properties and fatigue resistance of pre-strained aluminium alloys. Eur. J. Mech. A Solids 29, 1008–1014 (2010)
Hertzberg, R.W.: On the calculation of closure-free fatigue crack propagation data in monolithic metal alloys. Mater. Sci. Eng. A 190, 25–32 (1995)
Hong, Y., Zhao, A., Qian, G., Zhou, C.: Fatigue strength and crack: initiation mechanism of very-high-cycle fatigue for low alloy steels. Metall. Mater. Trans. A 43(8), 2753–2762 (2012)
Marines-Garcia, I., Paris, P.C., Tada, H., Bathias, C.: Fatigue crack growth from small to long cracks in VHCF with surface initiations. Int. J. Fatigue 29(9–11), 2072–2078 (2007)
Miller, K.J.: Materials science perspective of metal fatigue resistance. Mater. Sci. Tech. 9(6), 453–462 (1993)
Mughrabi, H.: Specific features and mechanisms of fatigue in the ultra-high-cycle regime. Int. J. Fatigue 28, 1501–1508 (2006)
Mughrabi, H.: Microstructural fatigue mechanisms: cyclic slip irreversibility, crack initiation, non-linear elastic damage analysis. Int. J. Fatigue 57, 2–8 (2013)
Mughrabi, H., Höppel, H.W.: Cyclic deformation and fatigue properties of very fine-grained metals and alloys. Int. J. Fatigue 32(9), 1413–1427 (2010)
Naimark, O.B., Bayandin, Yu.V., Leontiev, V.A., Panteleev, I.A., Plekhov, O.A.: Structural-scaling transitions and thermodynamic and kinetic effects in submicro-(nano-)crystalline bulk materials. Phys. Mesomech. 12(5–6), 239–248 (2009)
Nicholas, T.: High Cycle Fatigue. A Mechanics of Material Perspective. Elsevier, Oxford (2006)
Nicolas, T.: Critical issues in high cycle fatigue. Int. J. Fatigue 21, 221–231 (1999)
Oborin, V.A., Bannikov, M.V., Naimark, O.B., Palin-Luc, T.: Scaling invariance of fatigue crack growth in gigacycle loading regime. Tech. Phys. Lett. 36(11), 1061–1063 (2010)
Oborin, V., Bannikov, M., Naimark, O., Froustey, C.: Long-range-correlation large-scale interactions in ensembles of defects: estimating reliability of aluminium alloys under dynamic cycling and fatigue loading. Tech. Phys. Lett. 37(3), 241–243 (2011)
Paris, P.C., Lados, D., Tada, H.: Reflections on identifying the real ΔKeffective in the Threshold Region and Beyond. Eng. Fract. Mech. 75, 299–305 (2008)
Peters, J.O., Ritchie, R.O.: Influence of foreign-object damage on crack initiation and early crack growth during high-cycle fatigue of Ti-6Al-4V. Eng. Fract. Mech. 67, 193–207 (2000)
Sakai, T.: Review and prospects for current studies on high cycle fatigue of metallic materials for machine structural use. J. Solid Mech. Mater. Eng. 3(3), 425–439 (2009)
Shanyavsky, A.A.: Simulation of Fatigue Fracture of Metals. Synergetics in Aviation. Monografiya, Ufa (2007)
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Research was supported by the Russian Foundation of Basic Research (project n. 17-01-00687a).
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Naimark, O.B. (2019). Multiscale Dynamics of Damage-Failure Transitions and Structures Control Under Intensive Loading. In: Matveenko, V., Krommer, M., Belyaev, A., Irschik, H. (eds) Dynamics and Control of Advanced Structures and Machines. Springer, Cham. https://doi.org/10.1007/978-3-319-90884-7_13
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