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HomeMaterials Science ForumMaterials Science Forum Vols. 503-504Texture Formation during ECAP of Aluminum Alloy AA...

Texture Formation during ECAP of Aluminum Alloy AA 5109

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Abstract:

The technical aluminum alloy AA 5109 with a strong cube rolling texture has been deformed at room temperature by equal channel angular pressing (ECAP) using three passes of route A. Samples for ECAP have been cut parallel and at 45° with respect to the rolling direction yielding different starting textures. The local texture after ECAP has been investigated by highenergy synchrotron radiation. It is characterized by typical shear components of face-centred cubic (fcc) metals which deviate from their ideal positions. The texture with respect to intensity and deviation from ideal positions of the components depends on the distance from the top of the extruded billet and changes from pass to pass. It is also strongly influenced by the starting texture. The texture gradient has been discussed in the light of Tóth’s flow line model. The texture results have also been compared with those of other fcc metals with different stacking fault energy.

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Periodical:

Materials Science Forum (Volumes 503-504)

Pages:

99-106

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.503-504.99

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Online since:

January 2006

Authors:

Werner Skrotzki, N. Scheerbaum, C.G. Oertel, Heinz Günter Brokmeier, Satyam Suwas, László S. Tóth

Keywords:

Aluminum (Al), Equal-Channel Angular Pressing (ECAP), Microstructure, Synchrotron Radiation (XRD), Texture

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© 2006 Trans Tech Publications Ltd. All Rights Reserved

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[1] T.G. Langdon, M. Furukawa, M. Nemoto and Z. Horita: JOM Vol. 52 (2000), p.30.

[2] W. Skrotzki, N. Scheerbaum, C. -G. Oertel, H. -G. Brokmeier, S. Suwas and L.S. Tóth: Solid State Phenomena (2005a), in press.

DOI: 10.4028/www.scientific.net/ssp.105.327

[3] W. Skrotzki, N. Scheerbaum, C. -G. Oertel, H. -G. Brokmeier, S. Suwas and L.S. Tóth: Solid State Phenomena (2005b), in press.

DOI: 10.4028/www.scientific.net/ssp.105.327

[4] W. Skrotzki, N. Scheerbaum, C. -G. Oertel, H. -G. Brokmeier, S. Suwas and L.S. Tóth: Mater. Sci. Forum (2006), in press.

[5] G.J. Baxter, D. Duly, P.L. Orsetti Rossi, C.M. Sellars, J.A. Whiteman, H.R. Shercliff and M.F. Ashby: Proc. 16th Risø Symposium (1995), p.267.

[6] L. Rabet, P. Ratchev, B. Verlinden and P. Van Houtte: Proc. 16 th Risø Symposium (1995), p.525.

[7] W. Skrotzki, B. Klöden, R. Tamm, C. -G. Oertel, U. Garbe and E. Rybacki: Textures Microstruct. Vol. 35 (2003), p.163.

DOI: 10.1080/07303300310001628733

[8] R. Hühne: Diploma Thesis, Dresden University of Technology (1997).

[9] V.M. Segal: Mater. Sci. Eng. A Vol. 197 (1995), p.157.

[10] L.S. Tóth, R. Arruffat Massion, L. Germain, S.C. Baik, and S. Suwas: Acta Mater. Vol. 52 (2004), p.1885.

DOI: 10.1016/j.actamat.2003.12.027

[11] L.S. Tóth: Adv. Eng. Mat. Vol. 5 (2003), p.308.

[12] J.R. Bowen: The Formation of Ultra-Fine Grained Model Aluminium and Steel Alloys (PhD Thesis, Univ. of Manchester 2000).

[13] J. -Y. Suh, H. -S. Kim, J. -W. Park and J. -Y. Chang: Scripta Mater. Vol. 44 (2001), p.677.

[14] I.N. Budilov, I.V. Alexandrov, Y.V. Lukaschuk, I.J. Beyerlein and V.S. Zhernaov: Ultrafine Grained Materials III (Y.T. Zhu, T.G. Langdon, R.Z. Valiev, S.L. Semiatin, D.H. Shin and T.C. Lowe (eds. ), TMS 2004), p.193.

[15] L.S. Tóth and J.J. Jonas: Textures Microstruct. Vol. 10 (1989), p.195.

[16] B. Bacroix and J.J. Jonas: Proc. 8th Int. Conf. on Textures of Materials (ICOTOM 8) (J.S. Kallend and G. Gottstein (eds. ), The Metallurgical Society 1988), p.403.

[17] S. Suwas, L.S. Tóth, J. -J. Fundenberger, T. Grosdidier and W. Skrotzki: Solid State Phenomena (2005), in press.