Achieved limit thermal conductivity and enhancements of mechanical properties in fluorite RE3NbO7 via entropy engineering

Effective governance of thermal conductivity and other properties is of significant interest for science, including the fields of thermal barrier coatings, thermoelectric materials, and limit alloys. In this study, we investigated the impact of entropy engineering on properties of fluorite RE3NbO7, and limit thermal conductivity and strengthened mechanical properties are achieved. The solution strengthening mechanism leads to an 80% increase in toughness when the intrinsic stiffness and Young's modulus of the fabricated samples are identified via nanoindentation. Thermal conductivity is as low as 1.03-1.17 Wm(-1)K(-1) at 25-900 degrees C, drastically reducing the gap between experimental results and theoretical limit values of fluorite RE3NbO7. The limit thermal conductivity as well as enhanced thermal expansion coefficients (11.2x10(-6) K-1) and mechanical properties imply that the working performance of RE3NbO7 is evidently promoted by entropy engineering.

Automated summary

The study demonstrates that entropy engineering can significantly impact the properties of fluorite RE3NbO7, achieving limited thermal conductivity and enhanced mechanical properties. The thermal conductivity is reduced to as low as 1.03-1.17 Wm(-1)K(-1), while the mechanical properties are notably improved.