Thermal stability of Ag-doped Ni-Mn-Ga high-temperature shape memory alloy.

In the present study, the microstructure features and martensitic transformation behaviour of a Ni-Mn-Ga alloy were tailored by adjusting the Ag content. In addition, the effect of Ag content on the thermal stability was also explored. The results revealed that the non-modulated martensite phase and Ag particles coexisted in the Ni-Mn-Ga-Ag alloys. Different martensite variants were in the {112} type I twinning relationship. With increasing Ag content, not only all transformation temperatures but also the thermal hysteresis decreased continuously in a quasilinear manner. This was attributed to the introduction of small and soft Ag particles, which were applied to release the elastic energy during the martensitic transformation. The decreasing trend of elastic energy was highly nonlinear. The alloy with 4 at% Ag addition was the percolation threshold. In addition, the relationship of energy dissipation against Ag is not monotonic. While the energy dissipation of Ni 48 Mn 25 Ga 19 Ag 8 is almost zero, the others were much higher. Furthermore, unlike others, Ni 48 Mn 25 Ga 19 Ag 8 featured good martensitic transformation stability upon thermal cycling. • A series of Ni-Mn-Ga-Ag alloys were investigated. • NM martensite plates and Ag particles were observed in Ni-Mn-Ga-Ag alloy. • Transformation temperatures and hysteresis decreased by increasing Ag contents. • Ni 48 Mn 25 Ga 19 Ag 8 exhibited good thermal cycling stability. [ABSTRACT FROM AUTHOR]