Tensile deformation behavior of Sn-5Sb, Sn-5Sb-1.5Bi, and Sn-5Sb-1.5Cu alloys was investigated at temperatures ranging from 298 to 400 K. and strain rates ranging from 5 x 10(-4) to 1 x 10(-2) S(-1). Addition of Bi and Cu into the binary alloy resulted in an increase in both ultimate tensile strength (UTS) and ductility. The improved strength of the Bi-containing alloy can be attributed to the microstructural refinement, uniform distribution of the SnSb intermetallic particles, and solid-solution hardening effect of bismuth in the beta-Sn matrix. The enhanced strength of the Cu-containing alloy was ascribed to the presence of the Cu(6)Sn(5) intermetallic particles and structural refinement. The ductility of both ternary alloys was, however, improved by the structural refinement, caused by the addition of alloying elements. The results of tensile tests indicate that the strength of all three alloys increase with increasing strain rate and decrease with testing temperature. The variation of ductility with strain rate showed a descending trend, while it exhibited a minimum at medium testing temperatures. Based on the obtained stress exponents and activation energies, it is proposed that the dominant deformation mechanism in Sn-5Sb is dislocation climb over the whole temperature range investigated. For the ternary alloys, however, grain boundary diffusion and dislocation climb are the deformation mechanisms at high and low temperatures, respectively.

• 出版日期2011-12-15