Transformation behavior and superelasticity of TiZrHfNiCoCu multi-component high-temperature shape memory alloys

•The area fraction of second phase increased with the increased in the amount of (TiZrHf).•The martensitic transformation start temperature increased with the increase in (TiZrHf).•Solution treated 50(TiZrHf) and 50.5(TiZrHf) HTSMAs showed clear superelasticity. Multi-component (TiZrHf)1Ni1.50Co0.60Cu0.90, (TiZrHf)1Ni1.48Co0.58Cu0.88, (TiZrHf)1Ni1.45Co0.57Cu0.86, and (TiZrHf)1Ni1.40Co0.54Cu0.82 high-temperature shape memory alloys (HTSMAs) were prepared by arc-melting and then microstructures, transformation temperatures, phase constituents and superelasticity were investigated by scanning electron microscope observation, differential scanning calorimetery, X-ray diffraction and dynamic mechanical analysis in tensile mode, respectively. The microstructure of solution treated TiZrHfNiCoCu HTSMAs specimens consisted of (TiZrHf)(NiCoCu)-type matrix and (TiZrHf)2(NiCoCu)-type second phase. The area fraction of the second phase increased from 1.7% to 17.2% with the increased in (TiZrHf) content from 50 at% to 52 at%. Martensitic transformation start temperature of the solution treated specimens increased from 53.5 °C to 188.7 °C with the increase in (TiZrHf) content from 50 at% to 52 at%. TiZrHfNiCoCu HTSMAs showed clear superelasticity in the solution treated state. The superelastic recovery strain of solution treated TiZrHfNiCoCu HTSMAs was in the range of 4.2–4.6% depending on the alloy composition.