Study of deformation stacking faults and dislocation microstructures in Cu–1Sn–Zn alloys

Study of deformation stacking faults and dislocation microstructures in Cu–1Sn–Zn alloys

Microstructural parameters of plastically deformed (hand filed) Cu–1Sn–Zn ternary alloys with zinc concentration 10–24 wt.% are studied with X-ray diffraction line profile analysis. It is observed that unlike the binary alloy system, the stacking fault probability calculated from peak shift analysis...

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Bibliographic Details
Published in:Acta materialia Vol. 53; no. 17; pp. 4635 - 4642
Main Authors: Dey, S.N., Chatterjee, P., Sen Gupta, S.P.
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-10-2005
Elsevier Science
Subjects:
Applied sciences
COPPER ALLOYS (40 TO 99.3 CU)
Copper base alloys
Correlation
Cu–1Sn–Zn Alloys
DEFORMATION
Dislocation induced strain broadening
DISLOCATIONS
Exact sciences and technology
MATHEMATICAL ANALYSIS
Metals. Metallurgy
Microstructure
MICROSTRUCTURES
Stacking fault energy
Stacking fault probability
STACKING FAULTS
X-ray diffraction
Zinc
X-ray diffraction
Stacking fault energy
Cu–1Sn–Zn Alloys
Dislocation induced strain broadening
Stacking fault probability
Deformation
Tin alloy
Stacking fault
Copper base alloys
X ray diffraction
Dislocation
Cu-lSn-Zn Alloys
Microstructure
Zinc alloy
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Summary:Microstructural parameters of plastically deformed (hand filed) Cu–1Sn–Zn ternary alloys with zinc concentration 10–24 wt.% are studied with X-ray diffraction line profile analysis. It is observed that unlike the binary alloy system, the stacking fault probability calculated from peak shift analysis is almost constant with increase in zinc concentration from 10 to 20 wt.% and thereafter increases with the increase of zinc concentration. Stacking fault energy is calculated by modifying the expression given by Reed and Schramm [J Appl Phys 1974;45:4705] and shows a significant difference with that from earlier work by Ghosh and Sen Gupta [J Appl Phys 1983;54:6652]. Present results are closer to electron microscope studies. It is found that dislocation density is much higher (∼1015 m−2) and shows compositional dependence. Dislocation type is found to be a combination of equal populations of screw and edge dislocations. It is noticed from dislocation arrangement parameters that the dislocations are greatly correlated in nature for lower Zn concentration and less correlated at higher Zn concentration.
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ISSN:1359-6454
1873-2453
DOI:10.1016/j.actamat.2005.06.017