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Philosophical Magazine A Volume 62, 1990 - Issue 6
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Original Articles

Dislocation structures produced by low-amplitude fatigue of copper single crystals at 77 K

L. Buchinger Institut für Festkörperphysik der Universität Wien, A-1090 Wien, Strudlhofgasse, 4, Austria
,
S. Stanzl Institut für Festkörperphysik der Universität Wien, A-1090 Wien, Strudlhofgasse, 4, Austria
&
C. Laird Institut für Festkörperphysik der Universität Wien, A-1090 Wien, Strudlhofgasse, 4, Austria; Department of Materials Science and Engineering, University of Pennsylvania, Philadelphia, Pennsylvania, 19104-6272, U.S.A.
Pages 633-651 | Received 03 Jan 1990, Accepted 08 Jan 1990, Published online: 24 Oct 2006

Citations (25)

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L.W. Kong, Z.B. Xing, Y. Shu, Q.Q. Duan, Z.F. Zhang & P. Li. (2023) Effects of temperature and frequency on cyclic deformation behaviours of Cu single crystals. Philosophical Magazine 103:16, pages 1531-1552.
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H. Mayer. (1999) Fatigue crack growth and threshold measurements at very high frequencies. International Materials Reviews 44:1, pages 1-34.
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Uwe Holzwartht & Peter Hähner. (1995) Temperature dependence of the strain-rate sensitivity of persistent slip bands in copper single crystals. Philosophical Magazine A 72:3, pages 691-705.
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Uwe Holzwarth & Uwe Eßzmann. (1994) The irreversibility of dislocation-wall formation in persistent slip bands. Philosophical Magazine Letters 70:2, pages 75-80.
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Yu.G. Gordienko & E.E. Zasimchuk. (1994) Synergetic model of structure formation during plastic deformation of crystals. Philosophical Magazine A 70:1, pages 99-107.
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Articles from other publishers (20)

Farhan Ashraf & Gustavo M. Castelluccio. (2022) On the similitude relation for dislocation wall thickness under cyclic deformation. Materials Science and Engineering: A 840, pages 142972.
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Y. Li, S. X. Li, G. Y. Li & K. Lu. (2022) Cyclic deformation and dislocation structure evolution of a copper bicrystal with components rotating gradually along the grain boundary. International Journal of Materials Research 94:8, pages 871-875.
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Yabin Yan, Takashi Sumigawa, Xiaoyuan Wang, Wufan Chen, Fuzhen Xuan & Takayuki Kitamura. (2020) Fatigue curve of microscale single-crystal copper: An in situ SEM tension-compression study. International Journal of Mechanical Sciences 171, pages 105361.
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Katharina Diehl, Thorsten Staedler & Xin Jiang. (2019) Accessing fatigue information by means of dynamic nanoindentation. Applied Physics Letters 114:21.
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Jaroslav Polák & Jiří Man. (2014) Fatigue crack initiation – The role of point defects. International Journal of Fatigue 65, pages 18-27.
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M. Sauzay & L.P. Kubin. (2011) Scaling laws for dislocation microstructures in monotonic and cyclic deformation of fcc metals. Progress in Materials Science 56:6, pages 725-784.
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Peng Li, Shouxin Li, Zhongguang Wang & Zhefeng Zhang. (2010) Cyclic Deformation Behaviors of $$ [\bar{5}79] $$-Oriented Al Single Crystals. Metallurgical and Materials Transactions A 41:10, pages 2532-2537.
Crossref
Paul Paris & Claude Bathias. 2004. Gigacycle Fatigue in Mechanical Practice. Gigacycle Fatigue in Mechanical Practice.
Y. Li, S. X. Li, G. Y. Li & K. Lu. (2003) Cyclic deformation and dislocation structure evolution of a copper bicrystal with components rotating gradually along the grain boundary. Zeitschrift für Metallkunde 94:8, pages 871-875.
Crossref
Stefanie E. Stanzl-Tschegg. (2002) Dislocation and surface structures of copper and very-low-carbon steel at low fatigue amplitudes. Zeitschrift für Metallkunde 93:8, pages 799-805.
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H. Mayer, M. Papakyriacou, R. Pippan & S. Stanzl-Tschegg. (2001) Influence of loading frequency on the high cycle fatigue properties of AlZnMgCu1.5 aluminium alloy. Materials Science and Engineering: A 314:1-2, pages 48-54.
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M Papakyriacou, H Mayer, C Pypen, H PlenkJr.Jr. & S Stanzl-Tschegg. (2001) Influence of loading frequency on high cycle fatigue properties of b.c.c. and h.c.p. metals. Materials Science and Engineering: A 308:1-2, pages 143-152.
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Stanzl‐Tschegg. (2001) Fracture mechanisms and fracture mechanics at ultrasonic frequencies. Fatigue & Fracture of Engineering Materials & Structures 22:7, pages 567-579.
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J. Bretschneider, C. Holste & W. Kleinert. (1995) Mechanical behaviour and development of dislocation arrangements of f.c.c. single crystals fatigued at 77 K. Materials Science and Engineering: A 191:1-2, pages 61-72.
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V.A. Demkin. (1993) Ultrasonic fatigue of nickel-chromium alloys at low temperatures. IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control 40:6, pages 676-679.
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Jean‐Bernard Vogt, Thierry Magnin & Jacques Foct. (2007) EFFECTIVE STRESSES AND MICROSTRUCTURE IN CYCLICALLY DEFORMED 316L AUSTENITIC STAINLESS STEEL: EFFECT OF TEMPERATURE AND NITROGEN CONTENT. Fatigue & Fracture of Engineering Materials & Structures 16:5, pages 555-564.
Crossref
L. Llanes & C. Laird. (1993) Substructure evolution of copper polycrystals under different testing conditions: conventional strain control and ramp loading. Materials Science and Engineering: A 161:1, pages 1-12.
Crossref
V.A. Demkin. (1992) Fatigue fracture of polycrystalline nickel in a magnetic field at ultrasonic frequency. Scripta Metallurgica et Materialia 27:3, pages 319-324.
Crossref
Z.S. Basinski & S.J. Basinski. (1992) Fundamental aspects of low amplitude cyclic deformation in face-centred cubic crystals. Progress in Materials Science 36, pages 89-148.
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V. A. Demkin. (1991) Coercive Force and Electrical Resistivity of Polycrytalline Nickel after Low-Temperature Ultrasonic Fatigue. Physica Status Solidi (a) 128:2, pages 375-382.
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