Literature Cited
Method Instructions. Calculations and Tests for Strength in Machine Building. Methods of Mechanical Tests of Metals. Determination of the Characteristics of Fracture Toughness (Crack Resistance) in Static Loading. RD 50-260-81 [in Russian], Standartov, Moscow (1982).
G. A. Gogotsi, under the editorship of G. S. Pisarenko, Some Results of a Study of the Mechanical Properties of a Constructional Ceramic for Engine Parts [in Russian], Inst. Probl. Prochn. Akad. Nauk UkrSSR, Kiev (1982) (Preprint).
G. A. Gogotsi, The Inelasticity of Ceramics and Refractories [in Russian], Inst. Probl. Prochn. Akad. Nauk UkrSSR, Kiev (1982) (Preprint).
A. G. Evans, “A method for evaluating the time-dependent failure characteristics of brittle materials and its application to polycrystalline alumina,” J. Mater. Sci.,7, No. 10, 1137–1146 (1972).
S. M. Wiederhorn and L. H. Bolz, “Stress corrosion and static fatigue of glass,” J. Am. Ceram. Soc.,53, No. 10, 543–548 (1970).
V. P. Naumenko and V. A. Rakovskii, “The brittle fracture of a plate with a crack in transverse compression,” Probl. Prochn., No. 10, 7–12 (1981).
N. V. Novikov, I. M. Androsov, and A. L. Maistrenko, “A method of determination of the strength and crack resistance of polycrystalline superhard materials,” Sverkhtverd. Mater., No. 2, 33–37 (1982).
A. G. Evans and E. A. Charles, “Fracture toughness determination by indentation,” J. Am. Ceram. Soc.,59, No. 7-8, 371–372 (1976).
F. A. Gogotsi, V. P. Zavada, and A. N. Negovskii, “A method of studying the subcritical crack growth in a ceramic in double torsion of specimens,” Zavod. Lab.,48, No. 9, 83–85 (1982).
G. A. Gogotsi, V. P. Zavada, and V. P. Petrenko, “Determination of the crack resistance of a ceramic in bending of beams with a notch,” Poroshk. Metall., No. 1, 67–72 (1985).
R. L. Bertolotty, “Fracture toughness of polycrystalline Al2O3,” J. Am. Ceram. Soc.,56, No. 2, 107 (1973).
D. K. Bansal and W. H. Duckworth, “Fracture energy measurement by the notch-beam technique,” in: Fracture Mechanics Applied to Brittle Materials. ASTM STP 678 (1979), pp. 38–46.
B. J. Dalgleish, P. L. Pratt, and J. Sanford, “The fracture toughness—grain size relationship of polycrystalline aluminum,” Sci. Ceram., No. 8, 225–238 (1976).
L. A. Simpson, “Microstructural considerations for the application of fracture mechanics techniques,” Fract. Mech. Ceram.,2, No. 567–577 (1974).
B. J. Dalgleish, A. Fakhr, P. L. Pratt, and R. D. Rawlings, “Fracture toughness of alumina,” Ber. Dt. Ker. Ges.,55, No. 12, 511–514 (1978).
F. W. Kleinlein, “Einfluss der Versuchsfürhung auf die Bestimmung von Bruchkengrossen an spröden Werkstoffen, die langsame Rissausbreitung zeigen,” Ber. Dt. Ker. Ges.,57, No. 2, 17–22 (1980).
H. Hubner and W. Jillek, “Subcritical crack extension and crack resistance in polycrystalline alumina,” J. Mater. Sci.,12, No. 1, 117–125 (1977).
D. J. Green, P. S. Nicholson, and D. J. Embury, “Fracture toughness of a partially stabilized ZrO2 in the CaO−ZrO2 system,” J. Am. Ceram. Soc.,56, No. 12, 619–623 (1973).
Additional information
Institute of Strength Problems, Academy of Sciences of the Ukrainian SSR. Translated from Problemy Prochnosti, No. 4, pp. 3–8. April, 1985.
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Pisarenko, G.S., Gogotsi, G.A. & Zavada, V.P. Crack resistance of a constructional ceramic. Strength Mater 17, 445–451 (1985). https://doi.org/10.1007/BF01533939
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DOI: https://doi.org/10.1007/BF01533939