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S. Ya. Yarema, “The growth of fatigue cracks (method aspects of investigations),”, in: Methods and Means of Determining the Crack Resistance of Constructional Materials [in Russian], Naukova Dumka, Kiev (1981).
O. N. Romaniv, E. A. Shur, A. N. Tkach, V. N. Simin'kovich, and T. N. Kiseleva, “The kinetics and mechanism of fatigue crack growth in iron,” Fiz.-Khim. Mekh. Mater., No. 2, 57–66 (1981).
R. A. Smith, “On the short crack limitation of fracture mechanism,” Int. J. Fract.,13, No. 5, 717–720 (1977).
V. S. Ivanova and V. F. Terent'ev, The Nature of the Fatigue of Metals [in Russian], Metallurgiya, Moscow (1975).
G. P. Sheldon, T. S. Cook, J. W. Jones, and J. Lankford, “Some observations on small fatigue cracks En a superalloy,” Fatigue. End. Mater. Struct.,3, 219–228 (1981).
N. E. Frost, “Notch effects and the critical alternating stress required to propagate a crack in an aluminum alloy subject to fatigue loading,” J. Mech. Eng. Sci.,2, No. 2, 109–119 (1960).
O. N. Romaniv, V. N. Simin'kovich, and V. E. Litvinov, “Determining the fatigue crack resistance of surface hardened parts,” in: The Cyclic strength and Increasing the Supporting Capacity of Parts [in Russian], Izd. Perm. Politekh. fast., Perm (1981), pp. 59–60.
W. Hessler, H. Muller, B. Weiss, and R. Stickler, “Near-threshold behavior of polycrystalline copper,” Met. Sci., No. 5, 225–230 (1981).
N. E. Frost, “A relation between the critical alternating propagating stress and crack length for mild steel,” Proc. Inst. Mech. Eng.,173, 811–835 (1959).
H. Kitagawa and S. Takahashi, “Application of fracture mechanics to very small cracks or the cracks in the early stage,” in: Proc, 2nd Int. Conf. on Mech. Behav. of Mater., Boston, Mass. (1976), pp. 627–631.
K. Tanaka, Y. Nakai, and M. Yamashita, “Fatigue growth threshold of small cracks,” Int. J. Fract.,17, No. 5, 519–533 (1981).
J. Lankford, “On the small crack fracture mechanics problem,” Int. J. Fract.,16, No. 1, R7-R9 (1980).
M. H. El Haddad, K. N. Smith, and T. H. Topper, “Fatigue crack propagation of short cracks,” Trans. ASME, J. Eng. Mater. Technol.,101, No. 1, 42–46 (1979).
M. H. El Haddad, T. H. Topper, and K. N. Smith, “Prediction of nonpropagating cracks,” Eng. Fract. Mech.,11, No. 3, 573–584 (1979).
A. Ohta and E. Sasaki, “A method for determining the stress intensity threshold level for fatigue crack propagation,” Eng. Frac. Mech.,9, No. 3, 655–662 (1977).
V. M. Goritskii, “The evolution of the dislocation structure of iron during cyclic loading,” Authors's Abstract of Candidate's Dissertation, Technical Sciences, Moscow (1973).
M. Wilhelm, M. Nageswararao, and R. Meyer, “Factors influencing stage I crack propagation in agehardened alloys,” in: Fatigue Mechanisms. ASTM STP 675, Philadelphia, Pa. (1979), pp. 214–233.
V. M. Goritskii and V. F. Terent'ev, The Structure and Fatigue Fracture of Metals [in Russian], Metallurgiya, Moscow (1980).
A. Otsuka, “The origin and initial stage of propagation of a fatigue crack,” in: Proceedings of the 22nd Japanese National Symposium on Strength, Fracture, and Fatigue [Russian translation], (1977), pp. 1–27.
O. N. Romaniv, N. A. Deev, and I. S. Sorokivskii, “Some features of the mechanism of origin of fatigue cracks in high strength low-temperature tempered steels,” Fiz.-Khim. Mekh. Mater., No. 1, 41–47 (1975).
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Translated from Fiziko-Khimicheskaya Mekhanika Materialov, Vol. 18, No. 3, pp. 50–57, May–June, 1982.
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Romaniv, O.N., Simin'kovich, V.N. & Tkach, A.N. Near-threshold growth of short fatigue cracks. Mater Sci 18, 234–239 (1982). https://doi.org/10.1007/BF01150831
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DOI: https://doi.org/10.1007/BF01150831