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Metal Science Journal Volume 4, 1970 - Issue 1
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Articles

The Creep of Copper, Copper–10 at.-% Nickel, and Copper–10 at.-% Gold

B. L. Jones
&
C. M. Sellars
Pages 96-102 | Published online: 18 Jul 2013

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Read on this site (2)

W. J. Evans. (1976) A model for strain hardening during creep. Metal Science 10:5, pages 170-173.
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J. Hedworth & G. Pollard. (1971) The Influence of Stacking-Fault Energy on the Creep Behaviour of ∞-Brasses. Metal Science Journal 5:1, pages 41-46.
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Articles from other publishers (25)

J.Y. Yang, G.H. Kim & W.J. Kim. (2020) High-strain-rate solute drag creep in a Cu-22%Sn alloy (Cu17Sn3) with near peritectic composition. Materials Characterization 164, pages 110325.
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. 2015. Fundamentals of Creep in Metals and Alloys. Fundamentals of Creep in Metals and Alloys 301 332 .
Michael Mills & Glenn Daehn. 2011. Computational Methods for Microstructure-Property Relationships. Computational Methods for Microstructure-Property Relationships 311 361 .
. 2008. Fundamentals of Creep in Metals and Alloys. Fundamentals of Creep in Metals and Alloys 261 288 .
. 2004. Fundamentals of Creep in Metals and Alloys. Fundamentals of Creep in Metals and Alloys 243 267 .
J. J. Stephens & F. A. Greulich. (1995) Elevated temperature creep and fracture properties of the 62Cu-35Au-3Ni braze alloy. Metallurgical and Materials Transactions A 26:6, pages 1471-1482.
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M. S. Soliman. (2004) The influence of stacking fault energy on the creep behaviour of Ni-Cu-solid-solution alloys at intermediate temperatures. Journal of Materials Science 30:5, pages 1352-1356.
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Longquan Shi & D. O. Northwood. (2004) Dislocation network models for recovery creep deformation. Journal of Materials Science 28:22, pages 5963-5974.
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Oscar A. Ruano, Jeffrey Wolfenstine, Jeffrey Wadsworth & Oleg D. Sherby. (2005) Harper–Dorn and Power‐Law Creep in Single‐Crystalline Magnesium Oxide. Journal of the American Ceramic Society 75:7, pages 1737-1741.
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H. Siethoff. (1992) Steady-state deformation of copper solid-solution alloys. Physica Status Solidi (a) 131:2, pages 309-319.
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P. Gondi & A. Sili. (1991) A model for dislocation creep. Il Nuovo Cimento D 13:4, pages 505-516.
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R. J. Amodeo & N. M. Ghoniem. (1990) Dislocation dynamics. II. Applications to the formation of persistent slip bands, planar arrays, and dislocation cells. Physical Review B 41:10, pages 6968-6976.
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S.I. Hong. (1989) Influence of dynamic strain aging on the transition of creep characteristics of a solid solution alloy at various temperatures. Materials Science and Engineering: A 110, pages 125-130.
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Mahmoud S. Soliman & Ibrahim El-Galali. (1988) Appropriate diffusion coefficients for dislocation creep in solid-solution alloys. Journal of Materials Science Letters 7:10, pages 1027-1030.
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J.J. Urcola & C.M. Sellars. (1987) Effect of changing strain rate on stress-strain behaviour during high temperature deformation. Acta Metallurgica 35:11, pages 2637-2647.
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J. B. Fagbulu & O. Ajaja. (1987) Dislocation distributions and creep mechanisms. Journal of Materials Science Letters 6:8, pages 894-896.
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Sun Ig Hong. (1986) Influence of dynamic strain aging on the stress exponent and the dislocation substructure for the creep of Al?Mg alloys. Materials Science and Engineering 82, pages 175-185.
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M.J. Mills, J.C. Gibeling & W.D. Nix. (1986) Measurement of anelastic creep strains in Al-5.5 at.% Mg using a new technique: Implications for the mechanism of class I creep. Acta Metallurgica 34:5, pages 915-925.
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M.J. Mills, J.C. Gibeling & W.D. Nix. (1985) A dislocation loop model for creep of solid solutions based on the steady state and transient creep properties of Al-5.5 at.% Mg. Acta Metallurgica 33:8, pages 1503-1514.
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Yasuo Takahashi, Toshimi Yamane & Hiroshi Sasai. (1981) Grain Boundary Sliding in High Temperature Creep of a Precipitate-Free 25Cr–20Ni Austenitic Stainless Steel. Transactions of the Japan Institute of Metals 22:12, pages 865-872.
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M. M. Myshlyaev. (2006) Basic Processes of Creep and their Investigation in the EM. Kristall und Technik 14:10, pages 1185-1196.
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W. B. Durham, C. Goetze & B. Blake. (1977) Plastic flow of oriented single crystals of olivine: 2. Observations and interpretations of the dislocation structures. Journal of Geophysical Research 82:36, pages 5755-5770.
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S. Takeuchi & A.S. Argon. (1976) Steady-state creep of alloys due to viscous motion of dislocations. Acta Metallurgica 24:10, pages 883-889.
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S. Takeuchi & A. S. Argon. (1976) Steady-state creep of single-phase crystalline matter at high temperature. Journal of Materials Science 11:8, pages 1542-1566.
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Ryo Horiuchi & Masahisa Otsuka. (1972) Mechanism of High Temperature Creep of Aluminum- Magnesium Solid Solution Alloys. Transactions of the Japan Institute of Metals 13:4, pages 284-293.
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