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Metal Science Volume 16, 1982 - Issue 10
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Articles

Creep fracture by coupled power-law creep and diffusion under multiaxial stress

A. C. F. Cocks
&
M. F. Ashby
Pages 465-474 | Published online: 18 Jul 2013

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H. Jin & A. P. Gerlich. (2019) Effects of intermetallic particles on cavitation during superplastic forming of aluminium alloy. Materials Science and Technology 35:12, pages 1428-1435.
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. (2013) Reflections on creep: a review of the mst archive. Materials Science and Technology 29:8, pages 893-899.
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A. R. Ragab. (2005) Creep rupture as a result of grain boundary cavitation including void shape changes. Materials Science and Technology 21:4, pages 399-407.
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H-Y Wu, S. Lee & J.-Y. Wang. (2002) Effect of inverted pressurisation profile on deformation characteristics of 5083 aluminium alloy during superplastic forming. Materials Science and Technology 18:4, pages 438-444.
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R. S. Mishra, S. P. Singh, A. M. Sriramamurthy & M. C. Pandey. (1995) Effect of grain boundary orientation on creep behaviour of directionally solidified nickel base superalloy (CM 247 LC alloy). Materials Science and Technology 11:4, pages 341-346.
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J. Lian & M. Suery. (1986) Effect of strain rate sensitivity and cavity growth rate on failure of superplastic material. Materials Science and Technology 2:11, pages 1093-1098.
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D. S. Wilkinson & C. H. Caceres. (1986) Mechanism of plastic void growth during superplastic flow. Materials Science and Technology 2:11, pages 1086-1092.
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J. Pilling, D. W. Livesey, J. B. Hawkyard & N. Ridley. (1984) Solid state bonding in superplastic Ti-6Al-4V. Metal Science 18:3, pages 117-122.
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Articles from other publishers (69)

Arpan Das. (2023) Creep Fracture Complexions. Journal of Materials in Civil Engineering 35:5.
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Xiao-Yan Wang, Wei Gong, Xiao Wang & Kun Yu. (2022) Numerical investigation of creep crack growth behavior of UNS N10003 alloy based on the creep damage model. International Journal of Pressure Vessels and Piping 200, pages 104838.
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Jingdong Hu, Changjun Liu, Fuzhen Xuan & Bo Chen. (2022) Modeling of cavity nucleation, early‐stage growth, and sintering in polycrystal under creep–fatigue interaction. Fatigue & Fracture of Engineering Materials & Structures 45:3, pages 882-903.
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Georg Siroky, Elke Kraker, Dietmar Kieslinger, Ernst Kozeschnik & Werner Ecker. (2020) Micromechanics-based damage model for liquid-assisted healing. International Journal of Damage Mechanics 30:1, pages 123-144.
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Saeed Z. Chavoshi, Lance T. Hill, Kenneth E. Bagnoli, Ryan.L. Holloman & Kamran M. Nikbin. (2020) A combined fugacity and multi-axial ductility damage approach in predicting high temperature hydrogen attack in a reactor inlet nozzle. Engineering Failure Analysis 117, pages 104948.
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Javier Reboul, Ankit Srivastava, Shmuel Osovski & Guadalupe Vadillo. (2020) Influence of strain rate sensitivity on localization and void coalescence. International Journal of Plasticity 125, pages 265-279.
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H. Jin. (2019) Optimization of Aluminum Alloy AA5083 for Superplastic and Quick Plastic Forming. Metallurgical and Materials Transactions A 50:8, pages 3868-3890.
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Qinghua Meng & Zhenqing Wang. (2019) Creep damage models and their applications for crack growth analysis in pipes: A review. Engineering Fracture Mechanics 205, pages 547-576.
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Johanna Eisenträger & Holm Altenbach. 2019. State of the Art and Future Trends in Material Modeling. State of the Art and Future Trends in Material Modeling 79 112 .
Gavin D. R. Hall & Derryl D. J. Allman. (2018) Stress Migration Modeling Using Probabilistic Physics of Failure. IEEE Transactions on Device and Materials Reliability 18:4, pages 508-519.
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Zheng-Yang Hu, Zhao-Hui Zhang, Xing-Wang Cheng, Qi Song, Shi-pan Yin, Hao Wang & Fu-Chi Wang. (2018) Microstructure evolution and tensile properties of Ti-(AlxTiy) core-shell structured particles reinforced aluminum matrix composites after hot-rolling/heat-treatment. Materials Science and Engineering: A 737, pages 90-93.
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Jia-nan Hu, Takuya Fukahori, Toshihide Igari, Yasuharu Chuman & Alan C.F. Cocks. (2018) Modelling of creep rupture of ferritic/austenitic dissimilar weld interfaces under mode I fracture. Engineering Fracture Mechanics 191, pages 344-364.
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M. Sobhy, M. A. Mahmoud, S. A. Fayek, J. A. Fawzy, A. Fawzy & G. Saad. (2017) Improved microstructure, thermal and tensile properties of Zn and graphine oxide nano sheets (GONSs) doped Sn–1 wt%Ag–0.5 wt%Cu for electronic assemblies. Journal of Materials Science: Materials in Electronics 28:24, pages 19181-19192.
Crossref
Gavin D. R. Hall & Derryl D. J. Allman. (2017) Interactions and self-healing of Cu vias during stress migration tests and implications for burn-in and design rule formulations. Interactions and self-healing of Cu vias during stress migration tests and implications for burn-in and design rule formulations.
Yong Shin Lee. (2016) Development of a Process Map for Wire Drawing of Pearlitic Steel by Finite Element Analysis Coupled with Damage Evolution. Key Engineering Materials 716, pages 652-658.
Crossref
Hanna Quintero & Ali Mehmanparast. (2016) Prediction of creep crack initiation behaviour in 316H stainless steel using stress dependent creep ductility. International Journal of Solids and Structures 97-98, pages 101-115.
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Jia-nan Hu, Takuya Fukahori, Toshihide Igari, Yasuharu Chuman & Alan C.F. Cocks. (2016) An evaluation of creep rupture strength of ferritic/austenitic dissimilar weld interfaces using cohesive zone modelling. Procedia Structural Integrity 2, pages 934-941.
Crossref
K.A. Padmanabhan & S. Balasivanandha Prabu. 2016. Reference Module in Materials Science and Materials Engineering. Reference Module in Materials Science and Materials Engineering.
Patrick T Summers, Yanyun Chen, Christian M Rippe, Ben Allen, Adrian P Mouritz, Scott W Case & Brian Y Lattimer. (2015) Overview of aluminum alloy mechanical properties during and after fires. Fire Science Reviews 4:1.
Crossref
X. Z. Li, Z. S. Shao & X. Y. Wang. (2015) Research into the effects of micromechanical parameters on creep failure in brittle rocks. Arabian Journal of Geosciences 8:10, pages 7763-7769.
Crossref
Y. Chen, S.B. Puplampu, P.T. Summers, B.Y. Lattimer, D. Penumadu & S.W. Case. (2015) Quantification of stress-induced damage and post-fire response of 5083 aluminum alloy. Materials Science and Engineering: A 641, pages 369-379.
Crossref
Qing Zhang, Weizheng Zhang & Youyi Liu. (2015) Evaluation and mathematical modeling of asymmetric tensile and compressive creep in aluminum alloy ZL109. Materials Science and Engineering: A 628, pages 340-349.
Crossref
J. A. Collins, G. P. Potirniche & S. R. Daniewicz. 2014. Mechanical Engineers' Handbook. Mechanical Engineers' Handbook 1 68 .
. 2015. Fundamentals of Creep in Metals and Alloys. Fundamentals of Creep in Metals and Alloys 301 332 .
Y. Chen, S. W. Case & B. Y. Lattimer. 2015. Fracture, Fatigue, Failure, and Damage Evolution, Volume 5. Fracture, Fatigue, Failure, and Damage Evolution, Volume 5 89 98 .
Ali Mehmanparast. (2014) Prediction of creep crack growth behaviour in 316H stainless steel for a range of specimen geometries. International Journal of Pressure Vessels and Piping 120-121, pages 55-65.
Crossref
S. Balasivanandha Prabu & K.A. Padmanabhan. 2014. Aluminum-lithium Alloys. Aluminum-lithium Alloys 221 258 .
Giovanni Noselli, Vikram S. Deshpande & Norman A. Fleck. (2013) An analysis of competing toughening mechanisms in layered and particulate solids. International Journal of Fracture 183:2, pages 241-258.
Crossref
Enrico Evangelista. 2011. Hot Deformation and Processing of Aluminum Alloys. Hot Deformation and Processing of Aluminum Alloys 301 352 .
. 2010. High Temperature Deformation and Fracture of Materials. High Temperature Deformation and Fracture of Materials 285 296 .
. 2010. High Temperature Deformation and Fracture of Materials. High Temperature Deformation and Fracture of Materials 230 238 .
. 2010. High Temperature Deformation and Fracture of Materials. High Temperature Deformation and Fracture of Materials 217 229 .
. 2010. High Temperature Deformation and Fracture of Materials. High Temperature Deformation and Fracture of Materials 206 216 .
A. Zolochevsky, S. Sklepus, T. H. Hyde, A. A. Becker & S. Peravali. (2009) Numerical modeling of creep and creep damage in thin plates of arbitrary shape from materials with different behavior in tension and compression under plane stress conditions. International Journal for Numerical Methods in Engineering 80:11, pages 1406-1436.
Crossref
P.D. NicolaouA.K. Ghosh & S.L. Semiatin. 2009. Fundamentals of Modeling for Metals Processing. Fundamentals of Modeling for Metals Processing 325 338 .
Horng-yu Wu, Jiin-her Hwang & Chui-hung Chiu. (2009) Deformation characteristics and cavitation during multiaxial blow forming in superplastic 8090 alloy. Journal of Materials Processing Technology 209:4, pages 1654-1661.
Crossref
Hua-Tang Yao, Fu-Zhen Xuan, Zhengdong Wang & Shan-Tung Tu. (2007) A review of creep analysis and design under multi-axial stress states. Nuclear Engineering and Design 237:18, pages 1969-1986.
Crossref
A. Zolochevsky, A. Galishin, S. Sklepus & G.Z. Voyiadjis. (2007) Analysis of creep deformation and creep damage in thin-walled branched shells from materials with different behavior in tension and compression. International Journal of Solids and Structures 44:16, pages 5075-5100.
Crossref
Horng-yu Wu, Chui-hung Chiu, Shyh-hung Sheu, Shyong Lee & Jian-yih Wang. (2007) Effect of Die Surface Roughness on Deformation Characteristics and Cavitation during Blow Forming in a Superplastic 5083 Alloy. MATERIALS TRANSACTIONS 48:9, pages 2483-2488.
Crossref
Horng-yu Wu, Jau-yuean Perng, Shyh-hung Shis, Chui-hung Chiu, Shyong Lee & Jian-yih Wang. (2006) Cavitation characteristics of a superplastic 5083 Al alloy during gas blow forming. Journal of Materials Science 41:22, pages 7446-7453.
Crossref
Joseph R. Pickens. 2005. Metalworking: Bulk Forming. Metalworking: Bulk Forming.
S.L. Semiatin & J.J. Jonas. 2005. Metalworking: Bulk Forming. Metalworking: Bulk Forming.
P.D. Nicolaou, R.E. Bailey & S.L. Semiatin. 2005. Metalworking: Bulk Forming. Metalworking: Bulk Forming.
. 2004. Tensile Testing. Tensile Testing 209 238 .
I. Charit & R.S. Mishra. (2004) Evaluation of microstructure and superplasticity in friction stir processed 5083 Al alloy. Journal of Materials Research 19:11, pages 3329-3342.
Crossref
Tsutomu Tanaka & Kenji Higashi. (2004) Cavitation Behavior in Superplastically Deformed Zn-22 mass%Al Alloy at Room Temperature. MATERIALS TRANSACTIONS 45:8, pages 2547-2551.
Crossref
M.E. Kassner & T.A. Hayes. (2003) Creep cavitation in metals. International Journal of Plasticity 19:10, pages 1715-1748.
Crossref
Hidetoshi Somekawa, Hiroyuki Watanabe & Kenji Higashi. (2003) The Grain Size Dependence on Diffusion Bonding Behavior in Superplastic Mg Alloys. MATERIALS TRANSACTIONS 44:4, pages 496-503.
Crossref
Byung-Nam Kim & Keijiro Hiraga. (2002) Simulation of cavitation processes in superplastic deformation. Metallurgical and Materials Transactions A 33:11, pages 3449-3455.
Crossref
A. R. Ragab. (2002) Creep Rupture Due to Material Damage by Cavitation. Journal of Engineering Materials and Technology 124:2, pages 199-205.
Crossref
A.R. Ragab. (2002) The prediction of creep rupture of pressurized tubes using a model for void growth and coalescence. International Journal of Mechanical Sciences 44:3, pages 601-620.
Crossref
CM. Lombard, A. K. Ghosh & S. L. Semiatin. (2001) An analysis of cavitation occurring in near-&gg titanium aluminide during superplastic deformation. Metallurgical and Materials Transactions A 32:11, pages 2769-2779.
Crossref
P. D. Nicolaou, S. L. Semiatin & A. K. Ghosh. (2000) An analysis of the effect of cavity nucleation rate and cavity coalescence on the tensile behavior of superplastic materials. Metallurgical and Materials Transactions A 31:5, pages 1425-1434.
Crossref
Hajime Iwasaki, Takasuke Mori, Mamoru Mabuchi & Kenji Higashi. (2000) Elevated Temperature Deformation and Fracture Mechanisms in High-Strain-Rate-Superplastic Si<SUB>3</SUB>N<SUB>4<I>p</I></SUB>/Al&ndash;Cu&ndash;Mg Composite. Materials Transactions, JIM 41:3, pages 367-375.
Crossref
P.D. Nicolaou & S.L. Semiatin. (1999) Modeling of cavity coalescence during tensile deformation. Acta Materialia 47:13, pages 3679-3686.
Crossref
S.L. Semiatin, V. Seetharaman, A.K. Ghosh, E.B. Shell, M.P. Simon & P.N. Fagin. (1998) Cavitation during hot tension testing of Ti–6Al–4V. Materials Science and Engineering: A 256:1-2, pages 92-110.
Crossref
P. D. Nicolaou & S. L. Semiatin. (1998) A theoretical investigation of the effect of material properties and cavity architecture/shape on ductile failure during the hot tension test. Metallurgical and Materials Transactions A 29:10, pages 2621-2630.
Crossref
Mohamed Zaki. (1998) Influence of hydrostatic pressure and multiaxial straining on cavitating superplastic materials. Metallurgical and Materials Transactions A 29:10, pages 2555-2561.
Crossref
K. Kannan, C. H. Hamilton & C. H. Johnson. (1998) A study of superplasticity in a modified 5083 Al-Mg-Mn alloy. Metallurgical and Materials Transactions A 29:4, pages 1211-1220.
Crossref
H. IWASAKI, M. MABUCHI & K. HIGASHI. (1997) THE ROLE OF LIQUID PHASE IN CAVITATION IN A Si3N4/Al-Mg-Si COMPOSITE EXHIBITING HIGH-STRAIN-RATE SUPERPLASTICITY. Acta Materialia 45:7, pages 2759-2764.
Crossref
Atul H. Chokshi & Terence G. Langdon. (1996) A model study of cavity growth in superplasticity using single premachined holes. Metallurgical and Materials Transactions A 27:9, pages 2532-2539.
Crossref
Mohamed Zaki. (1996) Micronecking and fracture in cavitated superplastic materials. Metallurgical and Materials Transactions A 27:4, pages 1043-1046.
Crossref
Xing-Gang Jiang, James C. Earthman & Farghalli A. Mohamed. (2004) Cavitation and cavity-induced fracture during superplastic deformation. Journal of Materials Science 29:21, pages 5499-5514.
Crossref
Yong-Shin Lee & Paul R. Dawson. (1993) Modeling ductile void growth in viscoplastic materials—Part I: Void growth model. Mechanics of Materials 15:1, pages 21-34.
Crossref
Paul Dawson, Young-Shin Lee & Ashish Kumar. (1992) Void growth in drawing and extension of ductile metals. Journal of Materials Processing Technology 32:1-2, pages 119-134.
Crossref
A.C.F. Cocks & A.A. Searle. (1991) Void growth by grain-boundary diffusion in fine grained materials. Mechanics of Materials 12:3-4, pages 279-287.
Crossref
Z. X. Guo, K. Higashi & N. Ridley. (1990) An experimental investigation of the superplastic forming behavior of a commercial al-bronze. Metallurgical Transactions A 21:11, pages 2957-2966.
Crossref
M.R. Myers, R. Pilkington & N.G. Needham. (1987) Cavity nucleation and growth in a 1%Cr−0.5%Mo steel. Materials Science and Engineering 95, pages 81-91.
Crossref
M.F. Ashby & B.F. Dyson. 1984. Fracture 84. Fracture 84 3 30 .

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