Strength and electrical conductivity of deformation-processed Cu-15 Vol Pct Fe alloys produced by powder metallurgy techniques

“…[23] They also observed that the resistivity of Cu±Fe, after furnace cooling to room temperature, remained high due to a significant amount of dissolved Fe, which did not readily precipitated from solid solution. [23] Slow cooling after heat treatment is therefore known to increase the conductivity of Cu±Fe microcomposites. [12] Verhoeven et al observed that the conductivity of Cu±Fe microcomposites could be increased by promoting precipitation of more Fe through repetitive intermediate heat treatments and slow cooling (15 h cooling to room temperature) during drawing and that the optimum properties for Cu±20 Fe were 62.2 % IACS (International Annealed Copper Standard) and 930 MPa.…”

“…[1,8] The higher resistivity of Cu±Fe wire is thought to be due to a higher contribution from impurity scattering, r imp . [1,23] The Cu matrix dissolves considerably more Fe than Nb at temperatures above around 250±300 C and Fe has a very large resistivity decrement in Cu. [23] Jerman et al investigated the temperature dependence of the resistivity in Cu±Fe and found that the resistivity increased dramatically starting at around 500 C due to the large contribution of r imp .…”

“…[1,23] The Cu matrix dissolves considerably more Fe than Nb at temperatures above around 250±300 C and Fe has a very large resistivity decrement in Cu. [23] Jerman et al investigated the temperature dependence of the resistivity in Cu±Fe and found that the resistivity increased dramatically starting at around 500 C due to the large contribution of r imp . [23] They also observed that the resistivity of Cu±Fe, after furnace cooling to room temperature, remained high due to a significant amount of dissolved Fe, which did not readily precipitated from solid solution.…”

“…[23] Jerman et al investigated the temperature dependence of the resistivity in Cu±Fe and found that the resistivity increased dramatically starting at around 500 C due to the large contribution of r imp . [23] They also observed that the resistivity of Cu±Fe, after furnace cooling to room temperature, remained high due to a significant amount of dissolved Fe, which did not readily precipitated from solid solution. [23] Slow cooling after heat treatment is therefore known to increase the conductivity of Cu±Fe microcomposites.…”

Copper-Iron Filamentary Microcomposites

“…[23] They also observed that the resistivity of Cu±Fe, after furnace cooling to room temperature, remained high due to a significant amount of dissolved Fe, which did not readily precipitated from solid solution. [23] Slow cooling after heat treatment is therefore known to increase the conductivity of Cu±Fe microcomposites. [12] Verhoeven et al observed that the conductivity of Cu±Fe microcomposites could be increased by promoting precipitation of more Fe through repetitive intermediate heat treatments and slow cooling (15 h cooling to room temperature) during drawing and that the optimum properties for Cu±20 Fe were 62.2 % IACS (International Annealed Copper Standard) and 930 MPa.…”

“…[1,8] The higher resistivity of Cu±Fe wire is thought to be due to a higher contribution from impurity scattering, r imp . [1,23] The Cu matrix dissolves considerably more Fe than Nb at temperatures above around 250±300 C and Fe has a very large resistivity decrement in Cu. [23] Jerman et al investigated the temperature dependence of the resistivity in Cu±Fe and found that the resistivity increased dramatically starting at around 500 C due to the large contribution of r imp .…”

“…[1,23] The Cu matrix dissolves considerably more Fe than Nb at temperatures above around 250±300 C and Fe has a very large resistivity decrement in Cu. [23] Jerman et al investigated the temperature dependence of the resistivity in Cu±Fe and found that the resistivity increased dramatically starting at around 500 C due to the large contribution of r imp . [23] They also observed that the resistivity of Cu±Fe, after furnace cooling to room temperature, remained high due to a significant amount of dissolved Fe, which did not readily precipitated from solid solution.…”

“…[23] Jerman et al investigated the temperature dependence of the resistivity in Cu±Fe and found that the resistivity increased dramatically starting at around 500 C due to the large contribution of r imp . [23] They also observed that the resistivity of Cu±Fe, after furnace cooling to room temperature, remained high due to a significant amount of dissolved Fe, which did not readily precipitated from solid solution. [23] Slow cooling after heat treatment is therefore known to increase the conductivity of Cu±Fe microcomposites.…”

Copper-Iron Filamentary Microcomposites

“…Lastly, Chen et al [26] found that the morphology of the eutectic phase in the Pb-Sn alloy transformed from a developed dendrite to a refined equiaxed grain under AMF. Furthermore, the application of AMF during the solidification process can also purify the melt and reduce macro-segregation and casting defects in the material [27][28][29][30][31].…”

Influences of Alternating Magnetic Fieldson the Growth Behavior and Distribution of the Primary Fe Phasein Cu-14Fe Alloys during the Solidification Process

Fe–Cu Nanocomposites by High Pressure Consolidation of Powders prepared by Electric Explosion of Wires