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Canadian Metallurgical Quarterly
The Canadian Journal of Metallurgy and Materials Science
Volume 18, 1979 - Issue 1
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Constrained Cavity Growth, Its Use in Quantifying Recent Creep Fracture Results

B. F. Dyson
Pages 31-38 | Published online: 29 Nov 2013

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Markian P. Petkov, Elsiddig Elmukashfi & Alan C.F. Cocks. (2022) Multi-scale modelling of creep cavity nucleation and growth in polycrystalline Type 316 stainless steel. Philosophical Magazine 102:23, pages 2362-2411.
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R. P. Skelton. (2017) Deformation, diffusion and ductility during creep – continuous void nucleation and creep-fatigue damage. Materials at High Temperatures 34:2, pages 121-133.
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D. V. V. Satyanarayana, U. Prakash, S. Khaple, R. G. Baligidad & V. V. S. Prasad. (2014) Creep behaviour of carbon containing Fe3Al alloy. Materials at High Temperatures 31:3, pages 258-265.
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D.V.V. Satyanarayana, G. Malakondaiah & D.S. Sarma. (2007) Analysis of tertiary creep in an NiAl hardened austenitic steel. Materials at High Temperatures 24:2, pages 79-91.
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M. W. Spindler. (2004) The multiaxial and uniaxial creep ductility of Type 304 steel as a function of stress and strain rate. Materials at High Temperatures 21:1, pages 47-54.
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D. A. Pelemo. (1992) Effects of notch geometry and impurity on creep fracture of low alloy steel. Materials Science and Technology 8:2, pages 163-170.
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A. H. Chokshi. (1987) Analysis of constrained cavity growth during high temperature creep deformation. Materials Science and Technology 3:8, pages 656-664.
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T. B. Gibbons, S. Osgerby, F. Gabrielli & V. Lupine. (1987) Factors controlling creep strength of cast Ni–Cr-base alloys. Materials Science and Technology 3:4, pages 268-274.
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V.V. Kutumbarao & G.W. Greenwood. (1986) Influence of gas bubbles on creep of copper under small shear stresses. Materials Science and Technology 2:2, pages 129-132.
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D. J. Smith & G. A. Webster. (1985) Fracture mechanics interpretation of multiple-creep cracking using damage-mechanics concepts. Materials Science and Technology 1:5, pages 366-372.
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W. J. Clegg & J. W. Martin. (1982) Diffusion creep threshold in two-phase alloys. Metal Science 16:1, pages 65-72.
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L.-E. Svensson & G. L. Dunlop. (1982) Growth mechanism of intergranular creep cavities in α-brass. Metal Science 16:1, pages 57-64.
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K. U. Snowden, D. S. Hughes & P. A. Stathers. (1981) Grain-boundary cavity growth during high-temperature creep and fatigue. Metal Science 15:2, pages 73-78.
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L.-E. Svensson & G. L. Dunlop. (1981) Growth of intergranular creep cavities. International Metals Reviews 26:1, pages 109-131.
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Articles from other publishers (101)

Guiqiu Liu, Shi Liu, Feng Xin, Yi Zhao, Delong Hu & Yan Zhang. (2022) Three-Dimensional Numerical Simulation of Creep Crack Growth Behavior for 316H Steel Using a Stress-Dependent Model. Mathematical Problems in Engineering 2022, pages 1-11.
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Stuart Holdsworth. (2019) Creep-Ductility of High Temperature Steels: A Review. Metals 9:3, pages 342.
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Jian-Feng Wen, Shan-Tung Tu, Fu-Zhen Xuan, Xue-Wei Zhang & Xin-Lin Gao. (2016) Effects of Stress Level and Stress State on Creep Ductility: Evaluation of Different Models. Journal of Materials Science & Technology 32:8, pages 695-704.
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Yanwei Dai, Donghuan Liu & Yinghua Liu. (2016) Mismatch Constraint Effect of Creep Crack With Modified Boundary Layer Model. Journal of Applied Mechanics 83:3.
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C. M. Omprakash, B. Srivathsa, M. Kamaraj & D. V. V. Satyanarayana. (2015) Creep Damage Evaluation of DS CM247 Nickel Base Superalloy Using Alternate Current Potential Drop Technique. Transactions of the Indian Institute of Metals 69:2, pages 241-245.
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