Figures index

From

Contribution of the GP Zones to the Hardening and to the Electrical Resistivity in Al10at.%Ag Alloy

Faiza Lourdjane, Azzeddine Abderrahmane Raho

American Journal of Materials Science and Engineering. 2015, 3(1), 7-10 doi:10.12691/ajmse-3-1-2
  • Figure 1. X-ray powder diffraction spectra of Al(a) and Al-Ag (b) as quenched solid solution
  • Figure 2. Isotherm hardness curve at 125°C
  • Figure 3. Transformed fraction during the GP zones precipitation at 125°C
  • Figure 4. Hardness curve variation of homogenized Alxat.%Ag alloys
  • Figure 5. Matrix solute atom concentration during the GP zones precipitation at 125°C
  • Figure 6. Contribution to the alloy hardening of the matrix, HVm, and that of the GP zones, HVGP, during the GP zones precipitation at 125°C.
  • Figure 7. Electrical resistivity variation of the alloy during the GP zones precipitation at 125°C
  • Figure 8. Electrical resistivity of homogenized Alxat.%Ag alloys.
  • Figure 9. Contributions to the alloy electrical resistivity of the matrix, ρm, and of the GP zones, ρGP, during the GP zones precipitation at 125°C
  • Figure 10. Variation of the hardness versus the electrical resistivity of the as quenched alloys
  • Figure 11. Variation of the hardness contribution versus the electrical resistivity contribution of the matrix during the GP zones precipitation
  • Figure 12. Variation of the hardness versus the electrical resistivity of the isothermal aged alloy