Effects of particle reinforcement and ECAP on the precipitation kinetics of an Al-Cu alloy

Härtel, M.; Wagner, S.; Frint, P.; Wagner, M.F.-X.

doi:10.1088/1757-899X/63/1/012080

Effects of particle reinforcement and ECAP on the precipitation kinetics of an Al-Cu alloy (bibtex)

by M. Härtel, S. Wagner, P. Frint, M.F.-X. Wagner

Abstract:

The precipitation kinetics of Al-Cu alloys have recently been revisited in various studies, considering either the effect of severe plastic deformation (e.g., by equal-channel angular pressing -- ECAP), or the effect of particle reinforcements. However, it is not clear how these effects interact when ECAP is performed on particle-reinforced alloys. In this study, we analyze how a combination of particle reinforcement and ECAP affects precipitation kinetics. After solution annealing, an AA2017 alloy (initial state: base material without particle reinforcement); AA2017 + 10 vol.-% Al₂O₃; and AA2017 + 10 vol.-% SiC were deformed in one pass in a 120° ECAP tool at a temperature of 140 °C. Systematic differential scanning calorimetry (DSC) measurements of each condition were carried out. TEM specimens were prepared out of samples from additional DSC measurements, where the samples were immediately quenched in liquid nitrogen after reaching carefully selected temperatures. TEM analysis was performed to characterize the morphology of the different types of precipitates, and to directly relate microstructural information to the endo- and exothermic peaks in our DSC data. Our results show that both ECAP and particle reinforcement are associated with a shift of exothermic precipitation peaks towards lower temperatures. This effect is even more pronounced when ECAP and particle reinforcement are combined. The DSC data agrees well with our TEM observations of nucleation and morphology of different precipitates, indicating that DSC measurements are an appropriate tool for the analysis of how severe plastic deformation and particle reinforcement affect precipitation kinetics in Al-Cu alloys.

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Reference:

Härtel, M., Wagner, S., Frint, P., Wagner, M.F.-X.: Effects of particle reinforcement and ECAP on the precipitation kinetics of an Al-Cu alloy, IOP Conference Series: Materials Science and Engineering 63, 012080, 2014.

Bibtex Entry:

@Article{Hartel2014,
  Title                    = {{Effects of particle reinforcement and {ECAP} on the precipitation kinetics of an {Al-Cu} alloy}},
  Author                   = {H\"{a}rtel, M. and Wagner, S. and Frint, P. and Wagner, M.F.-X.},
  Journal                  = {IOP Conference Series: Materials Science and Engineering},
  Year                     = {2014},
  Pages                    = {012080},
  Volume                   = {63},

  Abstract                 = {The precipitation kinetics of Al-Cu alloys have recently been revisited in various studies, considering either the effect of severe plastic deformation (e.g., by equal-channel angular pressing -- ECAP), or the effect of particle reinforcements. However, it is not clear how these effects interact when ECAP is performed on particle-reinforced alloys. In this study, we analyze how a combination of particle reinforcement and ECAP affects precipitation kinetics. After solution annealing, an AA2017 alloy (initial state: base material without particle reinforcement); AA2017 + 10 vol.-% Al\textsubscript{2}O\textsubscript{3}; and AA2017 + 10 vol.-% SiC were deformed in one pass in a 120° ECAP tool at a temperature of 140 °C. Systematic differential scanning calorimetry (DSC) measurements of each condition were carried out. TEM specimens were prepared out of samples from additional DSC measurements, where the samples were immediately quenched in liquid nitrogen after reaching carefully selected temperatures. TEM analysis was performed to characterize the morphology of the different types of precipitates, and to directly relate microstructural information to the endo- and exothermic peaks in our DSC data. Our results show that both ECAP and particle reinforcement are associated with a shift of exothermic precipitation peaks towards lower temperatures. This effect is even more pronounced when ECAP and particle reinforcement are combined. The DSC data agrees well with our TEM observations of nucleation and morphology of different precipitates, indicating that DSC measurements are an appropriate tool for the analysis of how severe plastic deformation and particle reinforcement affect precipitation kinetics in Al-Cu alloys.},
  Doi                      = {10.1088/1757-899X/63/1/012080},
  ISSN                     = {1757-8981},
  Url                      = {http://stacks.iop.org/1757-899X/63/i=1/a=012080?key=crossref.21ce425cdd225a2e107f51e0ca96088b}
}