Literature cited
A. A. Griffith, “The phenomena of rupture and flow in solids,” Phil. Trans. R. Soc. Ser. A,221, No. 1, 163–198 (1921).
P. C. Paris, M. P. Gomez, and W. E. Anderson, “A rational analytic theory of fatigue,” Trend Eng.,13, No. 1, 9–14 (1961).
H. H. Johnson and P. C. Paris, “Subcritical flaw growth,” Eng. Fract. Mech.,1, No. 1, 3–45 (1968).
S. Ya. Yarema, “The methodology of determination of the characteristics of crack development resistance (crack resistance) of materials in cyclic loading,” Fiz.-Khim. Mekh. Mater., No. 4, 100–110 (1981).
J. R. Rice, “Mechanics of crack tip deformation and extension by fatigue,” in: ASTM STP 415. Fatigue Crack Propagation, ASTM, Philadelphia (1967), pp. 247–309.
L. Kunz, Z. Knésl, and P. Lukás, “Macroscopic residual stress distribution at a fatigue crack tip,” Fatigue Eng. Mater. Struct.,2, No. 2, 279–287 (1979).
G. P. Cherepanov, The Mechanics of Brittle Fracture [in Russian], Nauka, Moscow (1974).
V. V. Panasyuk and A. E. Andreikiv, “A theory of determination of the critical crack opening,” in: The Mechanics of Deformed Bodies and Structures [in Russian], Mashinostroenie, Moscow (1973).
GOST 25.506-85. Methods of Mechanical Tests of Metals. Determination of the Characteristics of Crack Resistance (Fracture Toughness) in Static Loading [in Russian], Standartov, Moscow (1985).
“ASTM standard E 399-83. Standard test method for plane-strain fracture toughness of metallic materials,” in: Annual Book of ASTM Standards, Vol. 03.01 (1983), pp. 547–582.
RD 50-345-82. Method Instructions. Calculations and Tests for Strength. Methods of Mechanical Tests of Metals. Determination of the Characteristics of Crack Resistance (Fracture Toughness) in Cyclic Loading [in Russian], Standartov, Moscow (1983).
“ASTM standard E 647-83. Standard test method for constant-load-amplitude crack growth rates above 10−8 m/cycle,” in: Annual Book of ASTM Standards, Vol. 03.01 (1983), pp. 739–759.
Industry Standard 1 90268-78. Metals. A Method of Determination of Fatigue Crack Growth Rate [in Russian].
V. V. Popovich and S. Ya. Yarema, “A macrofractographic investigation of the fatigue failure of 65G steel with different heat treatments in relation to stress level,” Fiz.-Khim. Mekh. Mater., No. 1, 70–74 (1976).
P. J. Forsyth, “A two stage process of fatigue crack growth,” in: Proceedings of the Crack Propagation Symposium, Vol. 1, The College of Aeronautics, Cranfield (1962), pp. 94–96.
S. Ya. Yarema, “The stage nature of fatigue failure and its consequences,” Fiz.-Khim. Mekh. Mater., No. 6, 66–72 (1973).
S. Ya. Yarema and V. V. Popovich, “The influence of structure and stress concentration on the period of fatigue crack origin in 65G steel,” ibid., No. 2, 35–40 (1985).
A. V. Prokopenko and V. N. Torgov, “The surface properties and fatigue limit of a metal. Report 1. The relationship of the yield strength to depth of the layer,” Probl. Prochn., No. 4, 28–34 (1986).
A. M. Freudenthal, “New aspects of fatigue and fracture mechanics,” Eng. Fract. Mech.,6, No. 4, 775–793 (1974).
M. Ya. Leonov, P. M. Vitvitskii, and S. Ya. Yarema, “A theoretical and experimental investigation of elastoplastic deformations in tension of a plate with a slit,” in: The Theory of Plates and Shells; Proceedings of the Second All-Union Conference (Lvov, Sept. 15–21, 1961) [in Russian], Izd. Akad. Nauk UkrSSR, Kiev (1962), pp. 196–199.
W. Elber, “The significance of fatigue crack closure,” in: Damage Tolerance in Aircraft Structures. ASTM STP 486, ASTM, Philadelphia (1971), pp. 230–242.
C. Q. Bowles, A Study of the Crack Tip Geometry Resulting from Fatigue Crack Propagation in Air and Vacuum, Report LR-261, Department of Aerospace Engineering, Delft University of Technology, Delft (1978).
R. O. Ritchie, “Threshold for fatigue crack propagation: questions and anomalies,” in: Advances in Fracture Research: Proceedings of the 6th International Conference on Fracture (New Delhi, 1984), Vol. 1, Pergamon Press, Oxofrd, etc. (1984), pp. 235–260.
O. N. Romaniv, “The structural concept of fatigue thresholds of constructional alloys,” Fiz.-Khim. Mekh. Mater., No. 1, 106–116 (1986).
B. Budiansky and J. W. Hutchinson, “Analysis of closure in fatigue crack growth,” Trans. ASME. J. Appl. Mech.,45, No. 2, 267–276 (1978)
H. Fuhring and T. Seeger, “Dugdale crack closure analysis of fatigue crack under constant amplitude loading,” Eng. Fract. Mech.,11, No. 1, 99–12 (1979).
S. Ya. Yarema and O. D. Zinyuk, “Experimental simulation of fatigue crack closure,” Fiz.-Khim. Mekh. Mater., No. 4, 57–62 (1987).
O. N. Romaniv, A. N. Tkach, and Yu. N. Lenets, “The influence of the stressed state at the tip of a fatigue crack on its growth and closure in the near-threshold region,” ibid., No. 4, 44–50 (1985).
O. N. Romaniv, G. N. Nikiforchin, and B. N. Andrusiv, “The effect of crack closure and evaluation of the cyclic crack resistance of constructional steels,” ibid., No. 3, 47–61 (1983).
S. Ya. Yarema and O. D. Zinyuk, “The cyclic crack resistance of magnesium alloys in vacuum and humid and dry air,” ibid., No. 4, 26–43 (1986).
A. N. Tkach and Yu. N. Lenets, “The influence of frequency, loading asymmetry, and structure of 10GN2MFA steel on crack closure and growth close to the threshold ΔKth”, ibid., No. 4, 60–67 (1986).
A. Zeghloul and J. Petit, “Environmental sensitivity of small crack growth in 7075 aluminium alloy,” Fat. Eng. Mater. Struct.,8, No. 4, 341–348 (1985).
O. P. Ostash, V. T. Zhmur-Klimenko, E. M. Kostyk, and A. B. Kunovskii, “The influence of crack closure and load cycle asymmetry on kinetic fatigue failure curves at normal and low temperatures,” Fiz.-Khim. Mekh. Mater., No. 3, 58–63 (1987).
O. N. Romaniv, A. I. Tkach, Yu. N. Lenets, and A. A. Popov, “Fatigue crack growth in constructional steels at increased temperatures,” ibid., No. 2, 43–50 (1986).
D. Gan and J. Weertman, “Crack closure and crack propagation rates in 7050 aluminum,” Eng. Fract. Mech.,15, No. 1–2, 87–106 (1981).
A. B. Zlochevskii and A. N. Shuvalov, “Factors retarding fatigue crack growth after overloads,” Fiz.-Khim. Mekh. Mater., No. 2, 41–46 (1985).
V. T. Troshchenko, V. V. Pokrovskii, and V. G. Kaplunenko, “The influence of specimen dimensions on the characteristics of cyclic crack resistance of heat resistant steels. Report 1,” Probl. Prochn., No. 4, 3–9 (1986); “Report 2,” ibid., No. 6, 13–18 (1986).
Author information
Authors and Affiliations
Additional information
From materials of a paper for the First All-Union Conference on “The Fracture Mechanics of Materials” (Lvov, October 20–22, 1987).
Translated from Fiziko-Khimicheskaya Mekhanika Materialov, Vol. 23, No. 5, pp. 17–29, September–October, 1987.
Rights and permissions
About this article
Cite this article
Yarema, S.Y. Fundamentals and certain problems of fatigue fracture mechanics. Mater Sci 23, 454–464 (1987). https://doi.org/10.1007/BF01148670
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF01148670