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Novel high entropy (Y <sub>0.2</sub> Sm <sub>0.2</sub> Gd <sub>0.2</sub> Er <sub>0.2</sub> Ho <sub>0.2</sub> ) <sub>3</sub> NbO <sub>7</sub> nanofibers with ultralow thermal conductivity

Xiaoning Sun, Guoxun Sun, Meng Huang

2023Journal of the American Ceramic Society19 citationsDOIOpen Access PDF

Abstract

Abstract Thermal insulation materials can provide thermal protection in extreme environments. Ceramic fibers have played an important role in the thermal protection field at high temperatures due to the advantages of low density, high strength, low thermal conductivity, and excellent thermal stability. In this work, high entropy (Y 0.2 Sm 0.2 Gd 0.2 Er 0.2 Ho 0.2 ) 3 NbO 7 (5RE 3 NbO 7 ) nanofibers were fabricated by electrospinning and subsequent calcination. Defective fluorite‐structured 5RE 3 NbO 7 nanofibers were obtained when heated at 900°C. The research indicates that 5RE 3 NbO 7 nanofiber based porous ceramics present an ultralow thermal conductivity (0.0992 W/m·K, porosity of 78.18%), good thermal stability, and high spectral reflectance, which establish the foundation for applications in thermal insulation.

Topics & Concepts

Natural bond orbitalThermal stabilityThermal conductivityNanofiberMaterials sciencePorosityCeramicCalcinationThermalMineralogyAnalytical Chemistry (journal)Composite materialPhysicsThermodynamicsChemistryDensity functional theoryQuantum mechanicsBiochemistryChromatographyCatalysisHigh-Temperature Coating BehaviorsGlass properties and applicationsAerogels and thermal insulation
Novel high entropy (Y <sub>0.2</sub> Sm <sub>0.2</sub> Gd <sub>0.2</sub> Er <sub>0.2</sub> Ho <sub>0.2</sub> ) <sub>3</sub> NbO <sub>7</sub> nanofibers with ultralow thermal conductivity | Litcius