Effect of interface and configuration on dynamic mechanical properties of bilayer B4C/Al composites

IF 6.8 3区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of Science: Advanced Materials and Devices Pub Date : 2025-06-29 DOI:10.1016/j.jsamd.2025.100941

Tian Luo , Zhenlong Chao , Longtao Jiang , Shengpeng Chen , Siyun Li , Yanxiong Meng , Huimin Han , Shanqi Du , Bingzhuo Han , Runwei Zhang , Mingqi Liu , Guoqin Chen

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引用次数: 0

Abstract

Layered materials have gained widespread attention in armor protection due to their unique designability, structure-function integration, and cross-scale synergistic effects. The interface and material configuration are key determinants of the dynamic mechanical properties of layered materials. This study focuses on these factors by fabricating bilayer B₄C/Al composites with a continuous aluminum matrix and varying reinforcement content gradients. The resulting bilayer structure exhibited an interfacial tensile strength of up to 326 MPa, significantly surpassing the bonding strength of epoxy resin. Under dynamic loading, the continuous matrix structure demonstrated superior compressive strength and energy absorption capacity, due to efficient strain transfer and coordinated deformation facilitated by strong interfacial bonding, which enhanced the synergy between layers. Digital image correlation (DIC) analysis revealed that the strain transfer efficiency near the interface in the continuous matrix structure reached 78 %, markedly higher than the 19 % observed in bonded structures. Finite element simulations further elucidated the influence of reinforcement gradients on stress-strain distribution and failure mechanisms. A larger reinforcement gradient intensified strain mismatch near the interface, inducing premature shear failure in the hard layer due to transverse volumetric expansion. For optimal material configurations, the compressive strength of the soft layer should exceed the yield strength of the hard layer to facilitate plastic zone expansion during compression and promote continuous strain hardening. These findings highlight the critical role of interface design and structural configuration in governing the dynamic mechanical performance of layered materials.

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界面和结构对双层B4C/Al复合材料动态力学性能的影响

层状材料以其独特的可设计性、结构功能一体化和跨尺度协同效应在装甲防护领域受到广泛关注。界面和材料形态是层状材料动态力学性能的关键决定因素。本研究通过制备连续铝基和不同增强梯度的双层B4C/Al复合材料来研究这些因素。所得双层结构的界面抗拉强度高达326 MPa，明显超过环氧树脂的结合强度。在动载荷作用下，连续基体结构表现出优异的抗压强度和吸能能力，这是由于强的界面结合促进了有效的应变传递和协调变形，增强了层间的协同作用。数字图像相关（DIC）分析结果表明，连续基体结构在界面附近的应变传递效率达到78%，明显高于键合结构的19%。有限元模拟进一步阐明了配筋梯度对应力-应变分布的影响及破坏机制。较大的配筋梯度加剧了界面附近的应变失配，导致硬层由于横向体积膨胀而过早剪切破坏。对于最优的材料配置，软层的抗压强度应超过硬层的屈服强度，以促进压缩过程中塑性区扩展，促进连续应变硬化。这些发现强调了界面设计和结构配置在控制层状材料动态力学性能中的关键作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Science: Advanced Materials and Devices Materials Science-Electronic, Optical and Magnetic Materials

CiteScore

11.90

自引率

2.50%

发文量

审稿时长

47 days

期刊介绍： In 1985, the Journal of Science was founded as a platform for publishing national and international research papers across various disciplines, including natural sciences, technology, social sciences, and humanities. Over the years, the journal has experienced remarkable growth in terms of quality, size, and scope. Today, it encompasses a diverse range of publications dedicated to academic research. Considering the rapid expansion of materials science, we are pleased to introduce the Journal of Science: Advanced Materials and Devices. This new addition to our journal series offers researchers an exciting opportunity to publish their work on all aspects of materials science and technology within the esteemed Journal of Science. With this development, we aim to revolutionize the way research in materials science is expressed and organized, further strengthening our commitment to promoting outstanding research across various scientific and technological fields.