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Formation of Defect Structures during Annealing of Cold-deformed L10-ordered equiatomic FePd Intermetallics

Published online by Cambridge University Press:  26 February 2011

Anirudha R. Deshpande
Affiliation:
Department of Materials Science and Engineering, University of Pittsburgh, Pittsburgh, PA 15261, USA
Jörg M.K. Wiezorek
Affiliation:
Department of Materials Science and Engineering, University of Pittsburgh, Pittsburgh, PA 15261, USA
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Abstract

Planar defects produced in L10-ordered FePd during annealing after cold-deformation in the disordered cubic state have been characterized by transmission electron microscopy (TEM). The defects evolving during annealing include arrays of overlapping stacking faults (SF's), {111}-conjugated microtwins (μT's) and thermal antiphase boundaries (APB's). The defect formation mechanisms proposed here are similar to twinning mechanism reported for FCC-metals during annealing. Thus, SF arrays and faulted μT's in the L10-ordered FePd appear to form during the early stages of annealing by atomic attachment faulting on {111}-facets of the transformation interfaces. During later stages of annealing the reduced amount and the change in nature of the driving forces for the microstructural rearrangement result in changes in the predominant defect formation mechanism. The features of the defect genesis in L10-FePd are discussed with respect to solid-state transformations during processing of these ferromagnetic intermetallics.

Type
Research Article
Copyright
Copyright © Materials Research Society 2005

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References

REFERENCES

[1] Weller, D, Moser A. IEEE Trans Magn 1999;35:4423 Google Scholar
[2] Zhang, B, Lelovic, M, Soffa, WA. Scr. Metall Mater 1991;25:1577 Google Scholar
[3] Zhng, B, PhD thesis, University of Pittsburgh; 1991 Google Scholar
[4] Klemmer, T, Hoydick, D, Okumura, H, Zhang, B, Soffa, WA. Scr. Metall. Mater 1995;33:1793 Google Scholar
[5] Rao, M, Soffa, W A. Scr. Mater. (1997), 36:735.Google Scholar
[6] Klemmer, T, Soffa, WA.: Solid-Solid phase transformations. Warrendale: TMS; 1994 p969.Google Scholar
[7] Deshpande, A R, Wiezorek, JMK. J Magn Magn Mater (2004), 270:157.Google Scholar
[8] Deshpande, A R, Xu, H, Wiezorek, JMK Acta Mater. (2004) 52:2903 Google Scholar
[9] Klemmer, T J, PhD thesis, University of Pittsburgh (1995)Google Scholar
[10] Dash, S, Brown, N, Acta Metall. (1963) 11:1067 Google Scholar
[11] Mahajan, S, Pande, C S, Imam, M A, Rath, B B. Acta Mater. (1997), 45, 2633.Google Scholar
[12] Yanar, C, Radmilovic, V, Soffa, W A, Wiezorek, J M K. Intermetallics (2001), 9, 949 Google Scholar
[13] Gleiter, H, Acta Met. (1969), 17:565 Google Scholar
[14] Meyers, M A, Murr, L E, Acta Met. (1978), 26:951 Google Scholar