Structure, Texture, and Substructure of Foil in Sequential Rolling Steps of Cu–36.4 at % Pd Alloy

Structure, Texture, and Substructure of Foil in Sequential Rolling Steps of Cu–36.4 at % Pd Alloy

— The phase composition, texture, and substructure of foil of a Cu–36.4 at % Pd solid solution have been studied by X-ray diffractometry and electron diffraction after rolling to a thickness of 320, 220, 180, 100, and 30 μm and subsequent heat treatment in vacuum to a temperature exceeding the upper...

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Veröffentlicht in:Inorganic materials 2021-11, Vol.57 (11), p.1194-1200
Hauptverfasser: Ievlev, V. M., Dontsov, A. I., Gorbunov, S. V., Il’inova, T. N., Kannykin, S. V., Prizhimov, A. S., Roshan, N. R., Solntsev, K. A.
Format: Artikel
Sprache:eng
Schlagworte:
Beta phase
Chemistry
Chemistry and Materials Science
Copper base alloys
Deformation
Electron diffraction
Heat treating
Heat treatment
Industrial Chemistry/Chemical Engineering
Inorganic Chemistry
Materials Science
Metal foils
Parameters
Phase composition
Recrystallization
Solid solutions
Texture
Thickness
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container_end_page 1200
container_issue 11
container_start_page 1194
container_title Inorganic materials
container_volume 57
creator Ievlev, V. M.
Dontsov, A. I.
Gorbunov, S. V.
Il’inova, T. N.
Kannykin, S. V.
Prizhimov, A. S.
Roshan, N. R.
Solntsev, K. A.
description — The phase composition, texture, and substructure of foil of a Cu–36.4 at % Pd solid solution have been studied by X-ray diffractometry and electron diffraction after rolling to a thickness of 320, 220, 180, 100, and 30 μm and subsequent heat treatment in vacuum to a temperature exceeding the upper temperature stability limit of an ordered structure. The results demonstrate that the general trends of changes in texture observed at all foil thicknesses during both deformation and subsequent heat treatment are controlled by ordering processes according to the Bain model and disordering processes, with allowance for the role of rolling deformation and recrystallization during subsequent heat treatment. At all foil thicknesses, heat treatment of the deformed samples leads to a decrease in the lattice parameter of the α-phase and an increase in that of the β-phase, suggesting an increase in the percentage of Pd in the β-phase and a decrease in that in the α-phase. The small change in the lattice parameter of the α-phase ensures the possibility of a complete α → β transformation.
doi_str_mv 10.1134/S0020168521110054
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source SpringerNature Journals
subjects Beta phase
Chemistry
Chemistry and Materials Science
Copper base alloys
Deformation
Electron diffraction
Heat treating
Heat treatment
Industrial Chemistry/Chemical Engineering
Inorganic Chemistry
Materials Science
Metal foils
Parameters
Phase composition
Recrystallization
Solid solutions
Texture
Thickness
title Structure, Texture, and Substructure of Foil in Sequential Rolling Steps of Cu–36.4 at % Pd Alloy
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