Tailoring thermal expansion coefficient from positive through zero to negative in the compositional crossover alloy Ti50(Pd40Cr10) by uniaxial tensile stress

The precision control of thermal expansion is of fundamental interest and desirable for applications that require materials to retain their shape at different temperatures. In the present study, we propose that the thermal expansion coefficient can be tuned by uniaxial external stress for a single material embedded with nanoclusters, if the formation, growth or alignment of the nanoclusters depends on the external stress. We demonstrate the idea in a prototype alloy (Ti-50(Pd40Cr10)) located at the compositional crossover region between martensite and strain glass in the temperature-composition phase diagram of Ti-50(Pd50-xCrx). Its thermal expansion coefficient varies linearly from positive, through zero to negative values with increasing uniaxial tensile stress within 200 K similar to 300 K. The phase field simulations show that the volume fraction of nanoscale martensite variant favored by the external stress increases with stress, producing extra strain and compensating for the contraction of the austenite matrix on cooling. The degree of compensation leads to different thermal expansion coefficients. Such a tunable thermal expansion behavior occurs only in the cTossover compositions between martensite and strain glass, providing a design recipe for searching new systems with similar behavior. (C) 2020 The Authors. Published by Elsevier Ltd.

Automated summary

The precision control of thermal expansion is crucial for maintaining the shape of materials at different temperatures. By applying uniaxial external stress to a single material embedded with nanoclusters, the thermal expansion coefficient can be adjusted, as demonstrated in a prototype alloy. The tunable thermal expansion behavior is only observed in compositions between martensite and strain glass, providing a design recipe for new systems with similar behavior.