Martensite transformation, mechanical properties and shape memory effects of Ni-Mn-In-Mg shape memory alloys

The martensite transformation (MT), mechanical properties and shape memory effect (SME) of (Ni50Mn35In15)(1−x)Mgx (x = 0%, 0.08%, 0.3%, 0.6% at%) alloys were comprehensively investigated. The results showed that due to Mg doping the MT temperature shifted to higher temperatures and a worm-like second-phase precipitated at grain boundaries and inside the grains. With increasing Mg content, the amount of precipitates gradually increased, the thermal hysteresis was almost invariant, and the SME was not obviously affected at 3% pre-strain, even when the volume of the second phase reached up to 28.75%. Compressive stress and strain experiments showed that both the strain and strength of the Ni-Mn-In-Mg alloys were improved substantially (by 46.9% and 53.4%, respectively, at x = 0.6%) compared with those of the pure Ni50Mn35In15 alloy; this effect is nearly the same as that achieved by the directional solidification method. Because Mg is nonmagnetic, the magnetization difference of the alloy with Mg doping is much lower than that of the alloy without Mg doping. Overall, the results confirm that adding a small amount of Mg is a potentially viable method for improving the mechanical properties of Ni-Mn-In alloys without adversely damaging their functional properties. •Doping minor of Mg to the Ni-Mn-In alloys for the first time to investigate the martensite transformation and mechanical properties.•The method of adding minor of Mg element can effectively improve the mechanical properties of the alloy, and the effect is higher than that of by directional solidification method prepared.•The memory effect was not obviously damaged under the condition of 3% pre strain, even if there were 28.75% of the second phase precipitated.