High pressure torsion of Cu–Ag and Cu–Sn alloys: Limits for solubility and dissolution

“…Thus, under the influence of HPT in the alloy of titanium with cobalt, the accelerated mass transfer occurs at a rate of 12-13 orders of magnitude faster than the rate of ordinary thermal diffusion at room temperature (i.e., at the HPT temperature T HPT = 30 • C). We observed earlier the similar mass transfer, accelerated by HPT, in the study of HPT-driven competition between the decomposition of a solid solution and the dissolution of precipitates in copper alloys [25].…”

“…However, it saturates after 2-3 anvil rotations together with grain size and torsion torque [20,40]. Thus, the initial instabilities during HPT evolve into the steady state [25,[41][42][43][44][45] It should be noted that decreased amount of the ω-phase after HPT was also observed in Ti-Fe alloys with 0.5, 1, 2.2 and 4wt.% Fe, if the initial state consists of mostly α -martensite in the (α/α )-phase mixture [20,28]. This happens in alloys with lower content of Fe, such as 0.5 and 1%, annealed and quenched from 950 • C. In the latter case, the amount of the ω-phase appeared to be two times lower than in Ti-4wt.%Fe alloy and could be caused by solubility of~0.04 wt.% Fe in α -martensite as well.…”

“…As was noticed above, and presented in our previous works [20,28], in addition to diffusionless (and relatively fast) α→ω transformations, the processes associated with accelerated mass transfer also occur under HPT influence. In order to describe the mass transfer driven by HPT in copper and aluminum alloys, we estimated the equivalent diffusion coefficient [25]. Now we perform similar estimations for mixing in a titanium alloy.…”

“…The Ti 2 Co intermetallic particles appear light grey. After HPT, the Ti 2 Co particles remain almost unchanged (due to their high hardness, like in Cu-based alloys [25]). Figure 1 also presents bright-field ( Figure 1c) and dark-field ( Figure 1d) TEM micrographs, together with the selected area diffraction pattern (Figure 1e) for the (α + ω) matrix of the Ti-4wt.% Co alloy after HPT preliminary annealed at 600 • C (2774 h) after HPT.…”

Influence of β-Stabilizers on the α-Ti→ω-Ti Transformation in Ti-Based Alloys

“…Thus, under the influence of HPT in the alloy of titanium with cobalt, the accelerated mass transfer occurs at a rate of 12-13 orders of magnitude faster than the rate of ordinary thermal diffusion at room temperature (i.e., at the HPT temperature T HPT = 30 • C). We observed earlier the similar mass transfer, accelerated by HPT, in the study of HPT-driven competition between the decomposition of a solid solution and the dissolution of precipitates in copper alloys [25].…”

“…However, it saturates after 2-3 anvil rotations together with grain size and torsion torque [20,40]. Thus, the initial instabilities during HPT evolve into the steady state [25,[41][42][43][44][45] It should be noted that decreased amount of the ω-phase after HPT was also observed in Ti-Fe alloys with 0.5, 1, 2.2 and 4wt.% Fe, if the initial state consists of mostly α -martensite in the (α/α )-phase mixture [20,28]. This happens in alloys with lower content of Fe, such as 0.5 and 1%, annealed and quenched from 950 • C. In the latter case, the amount of the ω-phase appeared to be two times lower than in Ti-4wt.%Fe alloy and could be caused by solubility of~0.04 wt.% Fe in α -martensite as well.…”

“…As was noticed above, and presented in our previous works [20,28], in addition to diffusionless (and relatively fast) α→ω transformations, the processes associated with accelerated mass transfer also occur under HPT influence. In order to describe the mass transfer driven by HPT in copper and aluminum alloys, we estimated the equivalent diffusion coefficient [25]. Now we perform similar estimations for mixing in a titanium alloy.…”

“…The Ti 2 Co intermetallic particles appear light grey. After HPT, the Ti 2 Co particles remain almost unchanged (due to their high hardness, like in Cu-based alloys [25]). Figure 1 also presents bright-field ( Figure 1c) and dark-field ( Figure 1d) TEM micrographs, together with the selected area diffraction pattern (Figure 1e) for the (α + ω) matrix of the Ti-4wt.% Co alloy after HPT preliminary annealed at 600 • C (2774 h) after HPT.…”

Influence of β-Stabilizers on the α-Ti→ω-Ti Transformation in Ti-Based Alloys

“…But, for the CuSn8 alloy, the situation is more complex because of Sn solid solution that significantly affects the mobility of dislocations and also because this solid solution is metastable at room temperature [39]. During deformation, the high density of defects may promote atomic mobility and phase separation [40,41], and thus the precipitation of the Cu 3 Sn phase. X-Ray diffraction measurements were carried out (Fig.…”

Influence of strain rate and Sn in solid solution on the grain refinement and crystalline defect density in severely deformed Cu

Decrease of steady-state solubility of Ag in Cu by high-pressure torsion at low temperature