Abstract

The temperature and frequency dependent damping behavior of Ni added Mn-Cu alloys were investigated. Ni addition not only increased the magnitude of the phase-transformation damping peak, but also decreased its frequency dependence. A decreased transformation temperature was found in the Ni added Mn-Cu alloys under the same treating condition, which suggested a retarding effect of Ni on the decomposition of γ Mn phase during the slow-cooling process. The characteristic twin-boundary damping peak of Mn-Cu alloys was enlarged and broadened with the addition of Ni. According to the relaxation damping models the twin-boundaries in Ni added alloys had the larger activation energy, and also exhibited a broader distribution of relaxation time during the stress induced movement. In Ni added Mn-Cu alloys, the FCT γ Mn phase showed a larger axis ratio, c/a and the Cu-rich γ Mn phase coexisting with the FCT phase showed the similar lattice constants at ambient temperature. These microstructural features in Ni added Mn-Cu alloys might contribute to the improved damping behavior of the twin-boundary damping peak.

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