Preparation, mechanical, and thermal properties of CrNbO <sub>4</sub>: A novel dual-functional scale to protect RHEAs from oxidation and thermal attack
Shuang Zhang, Jian Zhang, Xiaohui Wang, Huimin Xiang, Fang Cheng, Wei Xie, Yanchun Zhou
Abstract
Cr-Nb containing refractory high-entropy alloys (RHEAs) excel in high strength beyond 1200°C but low density close to Ti-based alloys, which endow them promising for applications in aero engines. However, oxidation is the bottleneck that limits their practical applications. Recently, CrNbO<sub>4 </sub>has been found to effectively protect them from oxidation. Nevertheless, little is known about this oxide. To elucidate the protection mechanism of CrNbO<sub>4</sub> and explore its properties, we report herein for the first time the microstructure, mechanical, and thermal properties of CrNbO<sub>4</sub>. Using atomic-resolution high-annular dark field and annular bright field techniques, we confirmed the rutile-type structure of CrNbO<sub>4</sub>, identified the precipitation of Cr<sub>2</sub>O<sub>3</sub> and observed the Cr segregation at interface boundary between CrNbO<sub>4</sub> and Cr<sub>2</sub>O<sub>3</sub>. The Young's modulus (<em>E</em>), shear modulus (<em>G</em>), and bulk modulus (<em>B</em>) of CrNbO<sub>4</sub> are 253, 100, and 180 GPa, respectively, while the Vickers hardness (<em>H</em><sub>V</sub>), flexural strength (σ<sub>f</sub>), and fracture toughness (<em>K</em><sub>IC</sub>) of CrNbO<sub>4</sub> are 10.2±0.58 GPa, 205±8 MPa, and 1.54±0.12MPa·m<sup>1/2</sup>, respectively. The measured melting point of CrNbO<sub>4</sub> is 2053±20 K. The anisotropic thermal expansion coefficients (TEC) are α<sub>a</sub>=(5.38±0.09)×10<sup>-</sup><sup>6</sup>K<sup>-</sup><sup>1</sup>,α<sub>c</sub>=(7.44±0.14)×10<sup>-</sup><sup>6</sup>K<sup>-</sup><sup>1</sup>, and the average TEC is (6.07±0.12)×10<sup>-</sup><sup>6</sup> K<sup>-</sup><sup>1</sup>, which is close to that of refractory metals and RHEAs. Interestingly, the room temperature thermal conductivity of CrNbO<sub>4</sub> is 1.09 W·m<sup>-1</sup>·K<sup>-1</sup> and declines to 0.45 W·m<sup>-1</sup>·K<sup>-1</sup>at 1473 K, being lower than most of the currently well-known thermal insulation materials. Consequently, CrNbO<sub>4</sub> can be regarded as a novel dual functional scale on top of RHEAs to protect them from oxidation and thermal attack.