Amir Masoud Afsari Golshan, Hanieh Aroo & Mohammad Azadi. (2021) Sensitivity analysis for effects of heat treatment, stress, and temperature on AlSi12CuNiMg aluminum alloy behavior under force-controlled creep loading. Applied Physics A 127:1.
Crossref

. 2015. Fundamentals of Creep in Metals and Alloys. Fundamentals of Creep in Metals and Alloys 301 332 .

Kazuto Okayasu, Hiroki Takekoshi, Masayuki Sakakibara & Hiroshi Fukutomi. (2009) Role of Solute Atmosphere on the Texture Formation of Al-Mg Solid Solution during High-Temperature Uniaxial Compression Deformation. Journal of the Japan Institute of Metals 73:1, pages 58-63.
Crossref

. 2008. Fundamentals of Creep in Metals and Alloys. Fundamentals of Creep in Metals and Alloys 261 288 .

Eric M. Taleff, W.Paul Green, Mary-Anne Kulas, Terry R. McNelley & Paul E. Krajewski. (2005) Analysis, representation, and prediction of creep transients in Class I alloys. Materials Science and Engineering: A 410-411, pages 32-37.
Crossref

Mary-Anne Kulas, W. Paul Green, Eric M. Taleff, Paul E. Krajewski & Terry R. McNelley. (2005) Deformation mechanisms in superplastic AA5083 materials. Metallurgical and Materials Transactions A 36:5, pages 1249-1261.
Crossref

. 2004. Fundamentals of Creep in Metals and Alloys. Fundamentals of Creep in Metals and Alloys 243 267 .

M.E Kassner & M.-T Pérez-Prado. (2000) Five-power-law creep in single phase metals and alloys. Progress in Materials Science 45:1, pages 1-102.
Crossref

Yong LI & T.G. Langdon. (1998) Creep behavior of a reinforced Al-7005 alloy: Implications for the creep processes in metal matrix composites. Acta Materialia 46:4, pages 1143-1155.
Crossref

Brian D. Worth, J. Wayne Jones & John E. Allison. (1995) Creep deformation in near-γ TiAl: II. influence of carbon on creep deformation in Ti-48Al-1V-0.3C. Metallurgical and Materials Transactions A 26:11, pages 2961-2972.
Crossref

M. S. Soliman. (1995) Significance of solute concentration dependence of climb-controlled creep rates in dilute solid solution alloys. Journal of Materials Science Letters 14:16, pages 1155-1157.
Crossref

Taira Suzuki, Shin Takeuchi & Hideo YoshinagaTaira Suzuki, Shin Takeuchi & Hideo Yoshinaga. 1991. Dislocation Dynamics and Plasticity. Dislocation Dynamics and Plasticity 157 197 .

Hiroshi Oikawa, Masayuki Nakata & Shigeru Ito. (1988) Instantaneous Strain upon Sudden Stress Changes during Steady-State Creep of Dilute Al–Mg Alloys. Transactions of the Japan Institute of Metals 29:3, pages 208-215.
Crossref

Sun Ig Hong. (1987) On the creep activation energies of alloys. Materials Science and Engineering 86, pages 211-218.
Crossref

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.
Crossref

M. Uemura, T. Hyono, M. Umeno & H. Kawabe. (1986) High temperature deformation of Mn-Zn ferrite single crystals. Journal of Materials Science 21:7, pages 2257-2263.
Crossref

Derek O. Northwood & Ian O. Smith. (1986) Stress change tests during the steady state creep of aluminum alloy 3004 at 300°C. Materials Science and Engineering 79:2, pages 175-182.
Crossref

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.
Crossref

D. O. Northwood, L. Moerner & I. O. Smith. (1985) Effect of magnesium content on the stress exponent and effective stress in the steady state creep of Al-Mg alloys. Journal of Materials Science 20:5, pages 1683-1692.
Crossref

A. Nohara. (1985) Dislocation-structure changes during the dip tests and the dynamical internal stress in AlMg alloys at high temperatures. physica status solidi (a) 88:1, pages 213-222.
Crossref

Derek O. Northwood & I.O. Smith. (1985) Effect of magnesium content on the stress exponent and internal stress in the steady state creep of Al-Mg alloys. Scripta Metallurgica 19:3, pages 279-284.
Crossref

I.O. Smith & D.O. Northwood. 1985. Strength of Metals and Alloys (ICSMA 7). Strength of Metals and Alloys (ICSMA 7) 779 784 .

M.J. Mills, J.C. Gibeling & W.D. Nix. 1985. Strength of Metals and Alloys (ICSMA 7). Strength of Metals and Alloys (ICSMA 7) 767 772 .

A. Kohara & T. Imura. (1984) Yield-Point Phenomenon in a β-CuZn Single Crystal at High Temperatures. Physica Status Solidi (a) 84:2, pages 501-507.
Crossref

Zenji Horita & Terence G. Langdon. (1983) The universal nature of the third power stress dependence for steady-state creep. Scripta Metallurgica 17:5, pages 665-670.
Crossref

Parviz Yavari & Terence G. Langdon. (1982) An examination of the breakdown in creep by viscous glide in solid solution alloys at high stress levels. Acta Metallurgica 30:12, pages 2181-2196.
Crossref

Takao Endo, Masaharu Tasaki, Masahiro Kubo & Takashi Shimada. (1982) High Temperature Deformation of an Al–5 at%Mg Alloy under Combined High Frequency Stresses. Transactions of the Japan Institute of Metals 23:11, pages 665-673.
Crossref

Parviz Yavari, Farghalli A. Mohamed & Terence G. Langdon. (1981) Creep and substructure formation in an Al-5% Mg solid solution alloy. Acta Metallurgica 29:8, pages 1495-1507.
Crossref

N. K. Gobran & F. M. Mansy. (1980) Stress dependence of creep mechanism of an Al-2wt%Mg alloy at high temperature. Physica Status Solidi (a) 62:2, pages K163-K165.
Crossref

J.C. Gibeling & W.D. Nix. (1980) The description of elevated temperature deformation in terms of threshold stresses and back stresses: A review. Materials Science and Engineering 45:2, pages 123-135.
Crossref

T. E. Howson, J. E. Stulga & J. K. Tien. (1980) Creep and stress rupture of oxide dispersion strengthened mechanically alloyed inconel alloy MA 754. Metallurgical Transactions A 11:9, pages 1599-1607.
Crossref

Katunori Abe, Hideo Yoshinaga & Shotaro Morozumi. (1979) A theoretical examination of the macroscopic measurement of the mean internal stress in a deforming material. Materials Science and Engineering 41:1, pages 65-73.
Crossref

C. Oytana, P. Delobelle & A. Mermet. (1979) Rheological analysis of stress change experiments during high temperature creep. Journal of Materials Science 14:3, pages 549-555.
Crossref

Seiichi KARASHIMA. (1979) Recent Studies on Mechanisms of High Temperature Creep of Metals. Tetsu-to-Hagane 65:7, pages 820-830.
Crossref

Hiroshi Oikawa, Daijiro Mizukoshi & Seiichi Karashima. (1978) Creep mechanism in Fe-1.8 At. Pct Mo alloy at high temperatures. Metallurgical Transactions A 9:9, pages 1281-1285.
Crossref

Hiroshi Oikawa, Katsuyoshi Sugawara & Seiichi Karashima. (1978) Creep Behavior of Al-2.2 at%Mg Alloy at 573 K. Transactions of the Japan Institute of Metals 19:11, pages 611-616.
Crossref

Hiroshi Oikawa & Katsuyoshi Sugawara. (1978) Instantaneous plastic strain associated with stress increments during the steady state creep of Al and Al-5.5 At. Pct. Mg alloy. Scripta Metallurgica 12:1, pages 85-89.
Crossref

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.
Crossref

Hideo Yoshinaga, Ken Toma & Shotaro Morozumi. (1976) The High-Temperature Deformation Mechanism in Al–Mg Alloys and the Internal Stress. Transactions of the Japan Institute of Metals 17:9, pages 559-570.
Crossref

K. Maruyama & S. Karashima. (1975) Theoretical Consideration of Measurement of Work-Hardening and Recovery Rates during High Temperature Creep. Transactions of the Japan Institute of Metals 16:11, pages 671-678.
Crossref

Hiroshi Oikawa & Seiichi Karashima. (1974) On the stress exponent and the rate-controlling mechanism of high-temperature creep in some solid solutions. Metallurgical transactions 5:5, pages 1179-1182.
Crossref

S. Karashima, K. Maruyama & N. Ono. (1974) An Analysis of Cell Formation due to Plastic Deformation Based on Dislocation Theory. Transactions of the Japan Institute of Metals 15:4, pages 265-272.
Crossref

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Some Activation Parameters in Steady-State Creep of Aluminium–Magnesium Alloys at High Temperatures

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