Diversity of the disorder and different-scale order during variations of severe deformation of copper

The systematic features of structural changes in the atomic order and disorder in copper samples after severe deformation of a copper bar by shear rolling were studied. Shear rolling was performed in rolls with longitudinal and transverse grooves and with combined grooves of both types. The performe...

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Bibliographic Details
Published inPhysics of the solid state Vol. 57; no. 1; pp. 87 - 95
Main Authors Samoilenko, Z. A., Ivakhnenko, N. N., Pushenko, E. I., Pashinskaya, E. G., Varyukhin, V. N.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 2015
Springer
Subjects
Comparative analysis
Copper products
Mechanical Properties
Physics
Physics and Astronomy
Physics of Strength
Plasticity
Solid State Physics
Conventional Rolling
Copper Sample
Atomic Order
Combine Rolling
Severe Deformation
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Summary:The systematic features of structural changes in the atomic order and disorder in copper samples after severe deformation of a copper bar by shear rolling were studied. Shear rolling was performed in rolls with longitudinal and transverse grooves and with combined grooves of both types. The performed treatment made it possible to increase the strength characteristics by 30% with a simultaneous increase in the plastic characteristics by 15% as compared to the conventional technology using smooth rolls. A variety of the atomic order formed under the deformations used was revealed in the form of four different-size structural groups: small crystals with long-range order (102–103 Å), strain clusters with mesoscopic order (100–400 Å), amorphous clusters with incipient order (15–30 Å), and regions with disordered atoms. It was shown that conditions favorable for the formation of a perfect combination of fine crystalline (37%) and cluster (13%) different-scale groups of atomic order (50%) in disorder (50%) are created in the sample subjected to rolling in the combined mode. It was found that, in the sample produced by conventional rolling technology, regions with disordered atoms dominate (∼80%), whereas fine crystalline (16%) and cluster (4%) structural groups create an insufficiently organized atomic order for achieving high parameters of mechanical strength and plasticity.
ISSN:1063-7834
1090-6460
DOI:10.1134/S1063783415010266