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Zeitschrift fuer Metallkunde/Materials Research and Advanced TechniquesVolume 96, Issue 1, January 2005, Pages 78-82

Mechanism and kinetics of aging of high-strength Cu-5 wt.% Ni-2.5 wt.% Ti(Article)

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  • aDepartment of Materials Science, Institute of Nuclear Sciences Vinca, North Macedonia
  • bFaculty of Technology and Metallurgy, Belgrade
  • cMax-Planck-Inst. fur Metallforschung, Inst. F. Nichtmetallische A.M., Universität Stuttgart, Heisenbergstraß 3, D-70569 Stuttgart, Germany

Abstract

Light and scanning electron microscopy (SEM), X-ray diffraction analysis, hardness and uniaxial tensile tests have been applied to study the mechanism and kinetics of aging of the Cu-5 wt.% Ni-2.5 wt.% Ti alloy under the influence of static and dynamic conditions. Hardening of alloy during aging is a consequence of precipitation of (Ni, Cu)3Ti secondary particles with the hcp crystal structure, i.e., the same as the η phase (Ni3Ti). During static (SSA) and dynamic strain aging (DSA), the strength of the alloy is increased compared to quench aging (QA). This effect is most pronounced during the dynamic process. The total concentration of vacancies participating in the process of DSA is increased compared to the vacancy concentration during SSA and QA. This may be explained by the fact that vacancies are not annihilated at dislocations, but their concentration is preserved through the vacancy - precipitate reaction.

Author keywords

HardeningStatic and dynamic strain agingVacancy concentration

Indexed keywords

Engineering controlled terms:Aging of materialsConcentration (process)Crystal structureDislocations (crystals)Precipitation (chemical)Reaction kineticsStrain hardeningTensile testing
Engineering uncontrolled termsDynamic strain aging (DSA)Quench aging (QA)Static and dynamic strain agingVacancy concentration
Engineering main heading:Copper alloys
  • ISSN: 00443093
  • CODEN: ZEMTA
  • Source Type: Journal
  • Original language: English
  • DOI: 10.3139/146.018075
  • Document Type: Article
  • Publisher: Carl Hanser Verlag

  Cancarević, M.; Max-Planck-Inst. fur Metallforschung, Inst. F. Nichtmetallische A.M., Universität Stuttgart, Heisenbergstraß 3, Germany;
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