Exceptional strength-toughness-hardness integrated B4C ceramics with synergistic reinforcement of nano-BN and in-situ ceramic phases

IF 12.7 1区材料科学 Q1 ENGINEERING, MULTIDISCIPLINARY

Composites Part B: Engineering Pub Date : 2024-10-25 DOI:10.1016/j.compositesb.2024.111921

Heng Wang , Yi Zeng , Tianbin Zhu , Yibiao Xu , Yawei Li , Zhengyi Fu

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Abstract

Boron carbide (B₄C) ceramics with enhanced mechanical properties were fabricated by incorporating nano boron nitride (nano-BN), obtained through high-energy ball milling (HEBM) using ZrO₂ balls as the medium, and utilizing the spark plasma sintering (SPS) technique. During the densification process of B₄C/nano-BN composite powders, an in-situ reaction between the B₄C matrix and ZrO₂ resulted in the formation of ZrB₂ ceramic phases at 1200–1300 °C. Additionally, the rapid sintering densification temperature of composites is reduced to 1500–1700 °C, approximately 80 °C lower than that required for pure B₄C ceramics. Notably, while maintaining a high relative density (99.5 %), the Vickers hardness, flexural strength, and fracture toughness of B₄C ceramics reinforced with synergistic effects of nano-BN and ZrB₂ fabricated at 1750 °C are significantly improved to reach values of 36.8 ± 0.15 GPa, 701 ± 12 MPa, and 5.01 ± 0.13 MPa m^1/2 respectively; representing an increase of 3.5 GPa (10.5 %), 225 MPa (47.3 %), and 1.72 MPa m^1/2 (52.3 %) compared to pure B₄C ceramics alone. The multiple reinforcement mechanisms including pinning effects provided by nano-BN and in-situ formed ZrB₂ ceramic phases, B₄C/ZrB₂ grain boundary pressure and intracrystalline pressure within B₄C, interlayer dislocations of nano-BN and turbulent layer of B₄C/BN boundaries contribute to energy dissipation during fracture processes, such as crack deflection, bridging, propagation hindrance and branching effect; ultimately resulting in exceptional strength-toughness-hardness integrated B₄C-based ceramics.

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具有优异强度-韧性-硬度的集成 B4C 陶瓷，纳米-BN 与原位陶瓷相协同增强

以 ZrO2 球为介质，通过高能球磨（HEBM）获得纳米氮化硼（nano-BN），并利用火花等离子烧结（SPS）技术，制造出机械性能更强的碳化硼（B4C）陶瓷。在 B4C/nano-BN 复合粉末的致密化过程中，B4C 基体与 ZrO2 在 1200-1300 °C 温度下发生原位反应，形成 ZrB2 陶瓷相。此外，复合材料的快速烧结致密化温度降低到 1500-1700 ℃，比纯 B4C 陶瓷所需的温度低约 80 ℃。值得注意的是，在保持高相对密度（99.5%）的同时，1750 ℃ 下制造的纳米氮化硼和 ZrB2 协同增强的 B4C 陶瓷的维氏硬度、抗弯强度和断裂韧性都得到了显著提高，达到 36.8 ± 0.15 GPa、701 ± 12 MPa 和 5.01 ± 0.13 MPa m1/2；与单独的纯 B4C 陶瓷相比，分别提高了 3.5 GPa (10.5%)、225 MPa (47.3%) 和 1.72 MPa m1/2 (52.3%)。纳米氮化硼和原位形成的 ZrB2 陶瓷相提供的钉扎效应、B4C/ZrB2 晶界压力和 B4C 内部的晶内压力、纳米氮化硼的层间位错和 B4C/BN 边界的湍流层等多重强化机制有助于断裂过程中的能量耗散，如裂纹偏转、桥接、传播阻碍和分支效应；最终形成了强度-韧性-硬度一体化的 B4C 基陶瓷。

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来源期刊

Composites Part B: Engineering 工程技术-材料科学：复合

CiteScore

24.40

自引率

11.50%

发文量

784

审稿时长

21 days

期刊介绍： Composites Part B: Engineering is a journal that publishes impactful research of high quality on composite materials. This research is supported by fundamental mechanics and materials science and engineering approaches. The targeted research can cover a wide range of length scales, ranging from nano to micro and meso, and even to the full product and structure level. The journal specifically focuses on engineering applications that involve high performance composites. These applications can range from low volume and high cost to high volume and low cost composite development. The main goal of the journal is to provide a platform for the prompt publication of original and high quality research. The emphasis is on design, development, modeling, validation, and manufacturing of engineering details and concepts. The journal welcomes both basic research papers and proposals for review articles. Authors are encouraged to address challenges across various application areas. These areas include, but are not limited to, aerospace, automotive, and other surface transportation. The journal also covers energy-related applications, with a focus on renewable energy. Other application areas include infrastructure, off-shore and maritime projects, health care technology, and recreational products.