(Ho0.25Lu0.25Yb0.25Eu0.25)2SiO5 high-entropy ceramic with low thermal conductivity, tunable thermal expansion coefficient, and excellent resistance to CMAS corrosion

Low thermal conductivity, compatible thermal expansion coefficient, and good calcium-magnesium-aluminosilicate (CMAS) corrosion resistance are critical requirements of environmental barrier coatings for silicon-based ceramics. Rare earth silicates have been recognized as one of the most promising environmental barrier coating candidates for good water vapor corrosion resistance. However, the relatively high thermal conductivity and high thermal expansion coefficient limit the practical application. Inspired by the high entropy effect, a novel rare earth monosilicate solid solution (Ho0.25Lu0.25Yb0.25Eu0.25)(2)SiO5 was designed to improve the overall performance. The as-synthesized (Ho0.25Lu0.25Yb0.25Eu0.25)(2)SiO5 shows very low thermal conductivity (1.07 W.m(-1).K-1 at 600 degrees C). Point defects including mass mismatch and oxygen vacancies mainly contribute to the good thermal insulation properties. The thermal expansion coefficient of (Ho0.25Lu0.25Yb0.25Eu0.25)(2)SiO5 can be decreased to (4.0-5.9)x10(-6) K-1 due to severe lattice distortion and chemical bonding variation, which matches well with that of SiC ((4.5-5.5)x10(-6) K-1). In addition, (Ho0.25Lu0.25Yb0.25Eu0.25)(2)SiO5 presents good resistance to CMAS corrosion. The improved performance of (Ho0.25Lu0.25Yb0.25Eu0.25)(2)SiO5 highlights it as a promising environmental barrier coating candidate.

Automated summary

Rare earth monosilicate solid solution (Ho0.25Lu0.25Yb0.25Eu0.25)(2)SiO5 shows promise as an environmental barrier coating candidate, demonstrating low thermal conductivity, a matching thermal expansion coefficient to SiC, and good resistance to CMAS corrosion.