The microstructure and the mechanical properties of Cu -Ag alloys with 7 and 24 wt.% Ag are investigated. The microstructure of the alloys is mostly determined by the silver content. That of Cu-24 wt.% Ag alloys consists of a Cu-rich solid solution and the eutectic. Otherwise, the microstructure of Cu-7 wt.% Ag alloys consists of primarily solidified dendrites of a Cu-rich solid solution and small Ag-rich particles. The composition strongly influences the work-hardening rate. In order to achieve an ultimate tensile strength of 1 GPa, a logarithmic cold-deformation strain, g, of about 3.7 is required (g = ln A 0 /A) for the 7 wt.% Ag alloy, whereas for Cu-24 wt.% Ag alloys g ¼ 3.1 is sufficient. In as-cast alloys with 7 wt.% Ag a strong segregation is observed, which, consequently, leads to a strong decrease of the age-hardening effect. Therefore, the Cu-7 wt.% Ag alloy has to be homogenised before aging. The application of Cu -Ag alloys with a Ag-content below 8 wt.%, i. e. an the maximum solubility at the eutectic temperature, bears mainly two advantages: (i) less addiction to shear-band formation, and (ii) a higher electrical conductivity in comparison to equivalently treated Ag-rich alloys due to the small Ag content. A. Gaganov et al.: Microstructural evolution and its effect on the mechanical properties of Cu -Ag microcomposites Z. Metallkd. 95 (2004) 6 Carl Hanser Verlag, München 425
Commercial melt-spun and HDDR Nd-Fe-B powders as well as mechanically alloyed Nd-Fe-B powders have been used for hot pressing and subsequent die upsetting. A comparison of all three types of magnets with respect to their magnetic properties and deformation behaviour is discussed in this paper. The highest values of remanence, , and energy density, , found for the die-upset melt-spun material can be explained in terms of its small Nd content of 14 at% and its high degree of texture connected with the strong shape anisotropy of the deformed nanocrystalline grains. Fracture surfaces of this material have coarse grains at the former flake boundaries which results in a coercivity, , of only 1 T. An energy density of has been measured for a die-upset mechanically alloyed material. In spite of a Nd content of 16 at% in this alloy, a remanence of 1.2 T and a coercivity of 1.6 T have been attained. The large coercivity is due to (i) a very homogeneous distribution of the Nd-rich intergranular phase, (ii) a grain size of only observed after die upsetting and (iii) the fact that there is no formation of faceted grains during hot deformation. The microstructure of HDDR magnets (14 at% Nd) has larger average grain sizes and some faceted grains. Consequently these magnets have the smallest values of the degree of texture, remanence, , and energy density, . By addition of further elements the coercivity of this material could be held at . After thermal demagnetization the three types of hot-deformed Nd-Fe-B magnets have a relatively large initial susceptibility, which is due to the presence of classical magnetic domains as well as interaction domains. For the investigated fine-grained Nd-Fe-B materials the deformation mechanism can be described by using a solution-precipitation creep model, governed by interface-reaction-controlled creep.
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