Materials & Design (Nov 2022)

Design of oxygen-doped TiZrHfNbTa refractory high entropy alloys with enhanced strength and ductility

  • L.K. Iroc,
  • O.U. Tukac,
  • B.B. Tanrisevdi,
  • O. El-Atwani,
  • M.A. Tunes,
  • Y.E. Kalay,
  • E. Aydogan

Journal volume & issue
Vol. 223
p. 111239

Abstract

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Refractory high entropy alloys (RHEAs) are considered promising materials for high-temperature applications due to their thermal stability and high-temperature mechanical properties. However, most RHEAs have high density (>10 g/cm3) and exhibit limited ductility at low temperatures and softening at high temperatures. In this study, we show that oxygen-doping can be used as a new alloy design strategy for tailoring the mechanical behavior of the TiZrHfNbTa alloy: a novel low-density (7.98 g/cm3) ductile RHEA. Even though the material is a single-phase BCC with some oxides at room temperature, secondary BCC and HCP nano-lamellar structures start to form above 600 °C in addition to the nano-twins which are shown to be stable up to 1000 °C. This alloy shows superior strength and compressive ductility due to the nanoengineered microstructure. The present study sheds light on tailoring the strength-ductility balance in RHEAs by controlling the microstructure of novel RHEAs at the nanoscale via oxygen-doping.

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