Issue 33

A. Shanyavskiy, Frattura ed Integrità Strutturale, 33 (2015) 8-16; DOI: 10.3221/IGF-ESIS.33.02 16 R EFERENCES [1] Ivanova, V.S., Synergetics. Strength and Fracture of Metallic Materials. Cambridge Intern. Science Publ., (1998). [2] Ebeling, V., Structures Formed by Irreversible Process. Introduction to the Theory of Dissipative Structures, (Russian translation), Mir, Moscow, (1979). [3] Haken, G., Synergetics. The Hierarchy of Instabilities in Self-Organized Systems and Devices, (Russian translation), Mir, Moscow, (1985). [4] Ivanova, V.S., Shanyavskiy, A.A., Quantitative fractography. Fatigue Fracture, (in Russian), Metallurgia, Cheliabinsk, (1988). [5] Shanyavskiy, A.A., Synergetical models of fatigue-surface appearance in metals: the scale levels of self-organization, the rotation effects, and density of fracture energy, in: G. N. Franziskonis (Ed.), Probamat-21st Century: Probabilities and Materials. Tests, Models and Applications for the 21st Century, NATO ASI Series, Kluwer Academic Publishers, 46 (1998) 11-44. [6] Linch, S.P., Mechanisms of fatigue and environment assisted fatigue, In: J.T.Fong (Ed.) Fatigue mechanisms, ASTM STP 675, ASTM, Philadelphia, (1978) 174-213. [7] Ritchie, R.O., Influence of microstructure on near-threshold fatigue-crack propagation in ultra-high strength steel, Met. Science, 8/9 (1977) 381-397. [8] Shanyavskiy, A.A., Rotational instability of metals deformation and fracture during fatigue crack propagation on the mesoscopic scale level, Part II, Fracture mechanisms, Physical mesomechanics (in Russian), 4(1) (2001) 81-95. [9] Scott D., Mills, G.H., Spherical debris – its occurrence, formation, and significance in rolling contact fatigue, Wear, 24 (1973) 235-240. [10] Hurriks, P., The occurrence of spherical particles in fretting, Wear, 27 (1974) 319-328. [11] Rabinovich, E., The formation of spherical wear particles, Wear, 42 (1977) 149-156. [12] Shanyavskiy A.A.: In: Aircrafts and Engines, The Science Works Inst. Research Civil Aviation (in Russian), 1, Moscow, (1980) 20-24. [13] Suresh, S., Ritchie, R.O., A geometric model for fatigue crack closure induced by fracture surface roughness, Met. Trans., 13A (1982) 1627-1631. [14] Minakava, K., McEvily, A.J., On crack closure in the near-threshold region, Scripta Met., 81(6) (1981) 937-940. [15] Smith, M.C., Smith, R.A., The formation of spherical debris in Mode II fatigue cracks, Wear, 1 (1982) 105-128. [16] Shanyavskiy, A.A., Development of semi-elliptic fatigue crack in AK6 aluminium alloy under biaxial loading, Fatigue Fract. Engng. Mater. Struct, 19(12) (1996) 1445-1458. [17] Shanyavskiy, A.A., Orlov, E.F., Fracture surface development in an overloaded D16T AI-based alloy subjected to biaxial loading. A fractographic analysis, Fatigue Fract. Engng. Mater. Struct., 20(2) (1997) 151-166. [18] Shanyavskiy A.A., Boutsev B.I., Isaev M.V., The formation of spherical particles by fretting as a result of contact between the fatigue-crack edges, Izvestia Akad. Nauk SSSR (in Russian), Metals, 4 (1985) 136-142.