Nacre-mimetic alternating architecture of AgSnO2 contact: Highly-efficient synergistic enhancement of in-situ self-repairing erosion resistance and naturally evolving impact resistance

IF 8.4 1区 材料科学 Q1 CHEMISTRY, PHYSICAL
Changhu Xu , Kai Wen , Zhe Wang , Jun Wang , Hailin Lu , Zesen Mao , Tianci Mao , Chongqing Fan , Jun Li
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Abstract

Synergistically enhancing the erosion and impact resistance of contacts poses a significant challenge for cutting-edge electrical equipment. Fortunately, mollusk shells in nature have evolved effective strategies to construct microstructures with superior erosion and impact resistance. Inspired by the structure of nacre, AgSnO2 contact material with hierarchical architectures has been designed and fabricated. The mechanistic link between microstructural evolution and dynamic erosion is studied through experiments combined with Computational Fluid Dynamics (CFD) and Finite Element Method (FEM) simulations. Results show that the reconstructed SnO2 skeleton endowed with a highly continuous and anisotropic ‘flowering'-like structure forms a continuous interpenetrating network with Ag, optimizing the conductive pathways on the molten pool surface. Additionally, the Ag-rich regions in the deeper layers on both sides of the molten pool offers a stable ‘nutrient-supply’ for the continuous ‘flowering’ reconstruction of the skeleton, exhibiting excellent in-situ self-repairing erosion resistance. Benefiting from this synergistic strategy, this skeleton is reconstructed based on its natural structure, which further disperses the stress and deformation concentration while inhibiting interfacial debonding, thereby reducing the formation of cracks and significantly enhancing the impact resistance. This work is expected to breakthrough erosion and impact resistance in extreme condition electrical contact materials through biomimetic microstructure design.

Abstract Image

Ag-SnO2接触的珍珠层模拟交替结构:高效协同增强原位自修复抗侵蚀性和自然演化抗冲击性
如何协同增强触点的抗侵蚀性和抗冲击性是尖端电气设备面临的一项重大挑战。幸运的是,自然界中的软体动物贝壳已经进化出了有效的策略来构建具有卓越抗侵蚀性和抗冲击性的微结构。受珍珠质结构的启发,我们设计并制造出了具有分层结构的 AgSnO2 触点材料。通过实验结合计算流体动力学(CFD)和有限元法(FEM)模拟,研究了微结构演变与动态侵蚀之间的机理联系。结果表明,重构的二氧化锡骨架具有高度连续和各向异性的 "开花 "状结构,与银形成连续的互穿网络,优化了熔池表面的导电路径。此外,熔池两侧深层的富银区域为骨架的连续 "开花 "重建提供了稳定的 "营养供应",表现出卓越的原位自我修复抗侵蚀能力。得益于这种协同策略,骨架在其天然结构的基础上得以重构,从而进一步分散了应力和变形集中,同时抑制了界面脱粘,从而减少了裂缝的形成,并显著增强了抗冲击性。这项工作有望通过仿生微结构设计,突破极端条件下电接触材料的抗侵蚀和抗冲击性能。
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 Materiomics
Journal of Materiomics Materials Science-Metals and Alloys
CiteScore
14.30
自引率
6.40%
发文量
331
审稿时长
37 days
期刊介绍: The Journal of Materiomics is a peer-reviewed open-access journal that aims to serve as a forum for the continuous dissemination of research within the field of materials science. It particularly emphasizes systematic studies on the relationships between composition, processing, structure, property, and performance of advanced materials. The journal is supported by the Chinese Ceramic Society and is indexed in SCIE and Scopus. It is commonly referred to as J Materiomics.
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