Saadia Boudekhani-Abbas scite author profile

Saadia Boudekhani-Abbas

3Publications

2Citation Statements Received

165Citation Statements Given

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105

138

Affiliations

University of Sciences and Technology Houari Boumediene

Publications

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On the groove pressing of Ni-W alloy: microstructure, texture and mechanical properties evolution

Koriche¹,

Boudekhani-Abbas²,

Azzeddine³

et al. 2018

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The microstructure, texture and mechanical properties of the Ni-14%W (wt.%) alloy with two different initial grain sizes and textures were investigated after groove pressing (GP) at 450 • C to 4 cycles using electron back scatter diffraction (EBSD) and microhardness measurements. The first series (I) was characterized by small equiaxed grains and cube dominant texture component, whereas the second series (II) had elongated grains and β-fiber texture. EBSD analysis has shown that GP processing led to a slight refinement (less than 15 %) of equiaxed grains in series I while greater refinement (∼ 55 %) of the mean spacing along normal direction was observed in series II. The texture did not drastically change from the initial one and was characterized by the weakening of the cube component in series I and rapid decrease of the copper component for series II. GP processing reduces the plastic anisotropy of the alloy with initial elongated granular microstructure very slightly.

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Texture, microstructure and mechanical properties evolution in Fe-x (x = 36 and 48 wt.%) Ni alloy after accumulative roll bonding

Boudekhani-Abbas

Tirsatine

Azzeddine

et al. 2018

IOP Conf. Ser.: Mater. Sci. Eng.

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Microstructural peculiarities and textural characteristics of Ni–W sheet alloy after accumulative roll-bonding and annealing

et al. 2020

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In the present study, the through thickness morphological and textural characteristics of a Ni-14W sheet, processed by accumulative roll-bonding (ARB) up to 4 cycles (ε = 3.2) and annealed at 1100 °C for 1 h, were investigated using electron backscatter diffraction. In the internal layers, the microstructure exhibited a small grains size free of twins and contained high fraction of low angle grain boundaries due the domination of {001}〈100〉 Cube orientation. At the surface layers, grains were coarser and contained high fraction of twins, while texture was characterized by retained shear components. The results showed that the heterogeneity of annealed microstructure texture decreased with the increasing number of ARB processing. Particle stimulated nucleation mechanism was evidenced at the vicinity of some bonding interfaces due to the presence of metallic inclusions resulting from wire-brushing procedure. As a result, the orientation of the new recrystallized grains was rather random and the grain size was stabilized by a pining effect which contributed to the microstructure heterogeneity. A successful bonding was achieved with increasing number of ARB cycles as shown by the transformation of interfaces into grain boundaries and their subsequent migration.

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