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Novel gradient ZrB <sub>2</sub> –MoSi <sub>2</sub> –SiC dense layer with enhanced emissivity and long‐term oxidation resistance at ultra‐high temperatures

Ling-Yu Yang, Shun Dong, Tangyin Cui, Jianqiang Xin, Guiqing Chen, Changqing Hong, Xinghong Zhang

2024Rare Metals18 citationsDOI

Abstract

Abstract The rapid evolution of hypersonic vehicle technologies necessitates robust thermal protection systems capable of withstanding extreme oxidative ablation. This study introduces a novel gradient‐architected ZrB 2 –MoSi 2 –SiC dense layer embedded within a lightweight three‐dimensional (3D) needled carbon fiber composite. Utilizing the volatility of ethanol and polycarbosilane, the ceramic slurry is selectively infused into targeted regions of the fibrous structure, optimizing the ZrB 2 to MoSi 2 ratio to enhance performance. The resulting dense layer exhibits exceptional emissivity, surpassing 0.90 in the 1–3 μm range and exceeding 0.87 in the 2–14 μm range. Moreover, it demonstrates remarkable oxidative ablation resistance. Specifically, at an optimized ZrB 2 to MoSi 2 ratio of 6:4, the dense layer achieves a minimal linear ablation rate of 0.015 μm·s −1 under a 1.5 MW·m −2 oxyacetylene flame for 1000 s. Even after exposure to oxyacetylene ablation at surface temperatures of approximately 1750 °C for 1000 s, the dense layer retains its structural integrity, highlighting its enduring oxidation resistance. The incorporation of MoSi 2 not only enhances emissivity but also fortifies the ZrO 2 and SiO 2 oxide layers, crucial for environments with elevated oxygen levels, thereby mitigating the active oxidation of SiC. This combination of high emissivity and long‐term oxidation resistance at ultra‐high temperatures positions the ZrB 2 –MoSi 2 –SiC dense layer as an exceptionally promising candidate for advanced thermal protection in hypersonic vehicles.

Topics & Concepts

Materials scienceEmissivityTerm (time)Layer (electronics)Temperature gradientOptoelectronicsComposite materialOpticsMeteorologyPhysicsQuantum mechanicsAdvanced ceramic materials synthesisMXene and MAX Phase MaterialsIntermetallics and Advanced Alloy Properties