X-Ray Diffraction Study of the Effects of Solutes on the Occurrence of Stacking Faults in Silver-Base Alloys

Abstract

The addition of the solutes cadmium, indium, and tin to silver increases the probability of deformation faults α in filings from 3×10⁻³ in pure silver to a maximum value of 45×10⁻³ at the highest concentrations of solute. In addition, the twin fault probability β measured from center of gravity displacements varies from 10×10⁻³ for pure silver to 30×10⁻³ for the alloys highest in tin or indium concentration. Lattice parameters a_hkl were determined from all available reflections of the cold‐worked and annealed specimens and plotted as a function of cos²θ/sinθ. By relating the large scatter of the individual a_hkl to the occurrence of deformation faults in the deformed material, the true lattice parameter, a₀(CW), and the deformation fault probabilities α of cold‐worked materials could be determined. There was an apparent decrease in lattice parameter of the deformed Ag‐Sn alloys which was largest (∼0.1%) for the greatest tin concentration (Ag‐9%Sn). Using Fourier analysis of line profiles, the effective particle sizes (D_e)_hkl and root mean square strains [〈εL²〉_av]_hkl^½ were determined. The measured effective particle sizes were anisotropic [(D_e)₁₁₁/(D_e)₂₀₀=1.7] and are primarily a consequence of deformation and twin faulting. The values for the compound fault probability (1.5α+β) from peak shift and asymmetry and from anisotropic particle sizes, i.e., from peak broadening, agreed rather well.