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The Philosophical Magazine: A Journal of Theoretical Experimental and Applied Physics
Series 8
Volume 2, 1957 - Issue 20
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Original Articles

The flow stress of polycrystalline aluminium

C. J. Ball Crystallographic Laboratory, Cavendish Laboratory, Cambridge, England
Pages 1011-1017 | Received 31 May 1957, Published online: 13 Sep 2006

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Oleg D. Sherby, Alfred Goldberg & Oscar A. Ruano . (2004) Solute-diffusion-controlled dislocation creep in pure aluminium containing 0.026 at.% Fe. Philosophical Magazine 84:23, pages 2417-2434.
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R. J. Dashwood & T. Sheppard. (1993) Effect of consolidation temperature on mechanical properties of rapidly solidified Al–7Mg–1 Zr alloy. Materials Science and Technology 9:8, pages 678-685.
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M. Cigdem & G. H. J. Bennett. (1991) Influence of ingot structure on properties of commercial purity aluminium under hot testing conditions. Materials Science and Technology 7:4, pages 321-329.
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F.R. Castro-Fernáandez & C.M. Sellars. (1989) Relationship between room-temperature proof stress, dislocation density and subgrain size. Philosophical Magazine A 60:4, pages 487-506.
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J.W. Wyrzykowski & M.W. Grabski. (1986) The Hall–Petch relation in aluminium and its dependence on the grain boundary structure. Philosophical Magazine A 53:4, pages 505-520.
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M. A. Zaidi & T. Sheppard. (1982) Development of microstructure throughout roll gap during rolling of aluminium alloys. Metal Science 16:5, pages 229-238.
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M. Sahoo & J.A. Lund. (1973) Substructure strengthening in an SAP alloy. Canadian Metallurgical Quarterly 12:4, pages 403-408.
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R. J. McElroy & Z. C. Szkopiak. (1972) Dislocation–Substructure–Strengthening and Mechanical–Thermal Treatment of Metals. International Metallurgical Reviews 17:1, pages 175-202.
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D. J. Abson & J. J. Jonas. (1970) The Hall–Petch Relation and High-Temperature Subgrains. Metal Science Journal 4:1, pages 24-28.
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P.C. J. Gallagher. (1967) The high temperature flow stress of single crystals of copper, silver and gold. Part I. The Philosophical Magazine: A Journal of Theoretical Experimental and Applied Physics 15:133, pages 51-83.
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P.B. Hirsch & D.H. Warrington. (1961) The flow stress of aluminium and copper at high temperatures. The Philosophical Magazine: A Journal of Theoretical Experimental and Applied Physics 6:66, pages 735-768.
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J. Holden. (1961) The formation of sub-grain structure by alternating plastic strain. The Philosophical Magazine: A Journal of Theoretical Experimental and Applied Physics 6:64, pages 547-558.
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P. Feltham. (1961) The flow stress of metals at low temperatures. The Philosophical Magazine: A Journal of Theoretical Experimental and Applied Physics 6:62, pages 209-215.
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N. Thompson & N.J. Wadsworth. (1958) Metal fatigue. Advances in Physics 7:25, pages 72-169.
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Articles from other publishers (47)

D. Andre, T. Burlet, F. Körkemeyer, G. Gerstein, J.S.K.-L. Gibson, S. Sandlöbes-Haut & S. Korte-Kerzel. (2019) Investigation of the electroplastic effect using nanoindentation. Materials & Design 183, pages 108153.
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Ronald W. Armstrong. (2019) Size effects on material yield strength/deformation/fracturing properties. Journal of Materials Research 34:13, pages 2161-2176.
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A. Wright, S. Koffel, S. Kraft, P. Pichler, J. Cambieri, R. Minixhofer & E. Wachmann. (2015) Thermo-mechanical ball bonding simulation with elasto-plastic parameters obtained from nanoindentation and atomic force measurements. Thermo-mechanical ball bonding simulation with elasto-plastic parameters obtained from nanoindentation and atomic force measurements.
A. Wright, A. Hutzler, A. Schletz & P. Pichler. (2014) Thermo-mechanical simulation of plastic deformation during temperature cycling of bond wires for power electronic modules. Thermo-mechanical simulation of plastic deformation during temperature cycling of bond wires for power electronic modules.
Manabu NakaiGoroh Itoh. (2014) The Effect of Microstructure on Mechanical Properties of Forged 6061 Aluminum Alloy. MATERIALS TRANSACTIONS 55:1, pages 114-119.
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A. Wright, S. Koffel, P. Pichler, H. Enichlmair, R. Minixhofer & E. Wachmann. (2013) On the thermo-mechanical modelling of a ball bonding process with ultrasonic softening. On the thermo-mechanical modelling of a ball bonding process with ultrasonic softening.
Oleg D. Sherby & Oscar A. Ruano. (2005) Rate-controlling processes in creep of subgrain containing aluminum materials. Materials Science and Engineering: A 410-411, pages 8-11.
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H.J McQueen & W Blum. (2000) Dynamic recovery: sufficient mechanism in the hot deformation of Al (<99.99). Materials Science and Engineering: A 290:1-2, pages 95-107.
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R.W. CAHN. 1996. Physical Metallurgy. Physical Metallurgy 2399 2500 .
L. M. Rybakova. (1994) Mechanical properties and substructure of metals. Metal Science and Heat Treatment 36:10, pages 507-513.
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A. S. Taha & F. H. Hammad. (1990) Application of the Hall-Petch Relation to Microhardness Measurements on Al, Cu, Al-MD 105, and Al-Cu Alloys. physica status solidi (a) 119:2, pages 455-462.
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R.A. Varin, K. Kurzydlowski & K. Tangri. (1986) A new approach to the temperature dependence of the yield stress in polycrystalline austenitic stainless steels. Materials Science and Engineering 80:1, pages L5-L9.
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A. Schedl, A.K. Kronenberg & J. Tullis. (1986) Deformation microstructures of Barre granite: An optical, Sem and Tem study. Tectonophysics 122:1-2, pages 149-164.
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E. S. Kayali & A. Plumtree. (1982) Stress-substructure relationships in cyclically and monotonically deformed wavy slip mode metals. Metallurgical Transactions A 13:6, pages 1033-1041.
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A. Plumtree & E.S. Kayali. 1982. Strength of Metals and Alloys (ICSMA 6). Strength of Metals and Alloys (ICSMA 6) 913 918 .
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Hugh J. McQueen. (2014) The Experimental Roots of Thermomechanical Treatments for Aluminum Alloys. JOM 32:2, pages 17-26.
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Alan K. Miller & Oleg D. Sherby. (1978) A simplified phenomenological model for non-elastic deformation: Predictions of pure aluminum behavior and incorporation of solute strengthening effects. Acta Metallurgica 26:2, pages 289-304.
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R.N. Gardner, T.C. Pollock & H.G.F. Wilsdorf. (1977) Crack initiation at dislocation cell boundaries in the ductile fracture of metals. Materials Science and Engineering 29:2, pages 169-174.
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H. J. McQueen. (1977) The production and utility of recovered dislocation substructures. Metallurgical Transactions A 8:6, pages 807-824.
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Jean-Claude C. Mercier, Douglas A. Anderson & Neville L. Carter. (1977) Stress in the lithosphere: Inferences from steady state flow of rocks. Pure and Applied Geophysics PAGEOPH 115:1-2, pages 199-226.
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Alan K Miller & Oleg D Sherby. (1976) On subgrain strengthening at high and low temperatures. Scripta Metallurgica 10:4, pages 311-317.
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Masanori Ueki & Tadahisa Nakamura. (1976) Substructural Strengthening by Hot Working in Two <I>FCC</I> Materials. Transactions of the Japan Institute of Metals 17:3, pages 139-148.
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H.J. McQUEEN & J.J. JONAS. 1975. Plastic Deformation of Materials. Plastic Deformation of Materials 393 493 .
A.Q. Khan, M. Brabers & L. Delaey. (1974) The Hall-Petch relationship in copper-based martensites. Materials Science and Engineering 15:2-3, pages 263-274.
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A. E. Abey. (1973) Effect of hydrostatic pressure on torsional stress‐strain curves of single‐crystal copper. Journal of Applied Physics 44:5, pages 2087-2092.
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M. Sahoo & J. A. Lund. (1973) Substructure and dispersion hardening in aged, cold worked, and annealed Al-4 wt pct Cu alloy. Metallurgical Transactions 4:1, pages 39-45.
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H. F. Fischmeister. (2011) Applications of quantitative microscopy in materials engineering. Journal of Microscopy 95:1, pages 119-143.
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A.W. Thompson & W.A. Backofen. (1971) The effect of grain size on fatigue. Acta Metallurgica 19:7, pages 597-606.
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F. H. Hammad, C. N. Ahlquist & W. D. Nix. (1970) High temperature work softening yield point phenomena in polycrystalline aluminum. Metallurgical Transactions 1:8, pages 2179-2183.
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C.N Ahlquist, R Gascaneri & W.D Nix. (1970) A phenomenological theory of steady state creep based on average internal and effective stresses. Acta Metallurgica 18:6, pages 663-671.
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H. J. McQueen. (2017) Deformation mechanisms in hot working. JOM 20:4, pages 31-38.
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