Abstract
High temperature shape memory alloys Ti50Ni25Pd25and Ti50Ni20Pd25Cu5were developed, characterized, and tensile tested in both martensite ( Mf− 50°C) and austenite ( Af+ 50°C) phases. The transformation temperatures of ternary Ti50Ni25Pd25alloy were increased by 11 to 12.5°C by substitution of Ni with 5 at% Cu. At the same time, transformation heat absorbed and released during forward and reverse martensitic transformation was also increased. In the martensite phase, the mechanical properties, that is, the stress for reorientation of martensite variants and fracture stress, were increased by 33 and 60 MPa, respectively, whereas the fracture strain was decreased by 1.5%. In the austenite phase, the critical stress for slip and fracture stress were increased by 62 and 40.9 MPa, respectively, whereas the fracture strain was decreased by 1.2%. The increase in both stresses was attributed to the solid solution strengthening by substitution of Ni atoms with relatively greater atomic radius of copper (Cu) atoms. The overall results suggest that the addition of 5 at% Cu in place of Ni in Ti50Ni25Pd25alloy is very beneficial to improving the mechanical and shape memory properties and increasing the transformation temperatures.
Highlights
NiTi shape memory alloys are widely used in many engineering and medical fields due to their outstanding superelastic and shape memory properties [1]
The yield stress and fracture stress in the austenite phase were increased by 62 and 40.9 MPa, respectively, whereas the fracture strain was decreased by 1.2%
(2) The transformation heat absorbed and released during forward and reverse martensitic transformation was increased by substitution of Ni with 5 at% Cu
Summary
NiTi shape memory alloys are widely used in many engineering and medical fields due to their outstanding superelastic and shape memory properties [1]. Alloying of Pd and Pt has got relatively more attention as compared to other ternary alloying elements, due to its comparable properties of high work output and good workability like NiTi alloys [11,12,13,14]. In addition to these properties, TiNiPd has narrow thermal hysteresis which is desired for fast and active control of actuators [11]
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