Nested structure role in the mechanical response of spicule inspired fibers.

IF 3.1 3区计算机科学 Q1 ENGINEERING, MULTIDISCIPLINARY Bioinspiration & Biomimetics Pub Date : 2024-05-20 DOI:10.1088/1748-3190/ad483e

Y Xiao, N Fani, F Tavangarian, C Peco

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Abstract

Euplectella aspergillummarine sponge spicules are renowned for their remarkable strength and toughness. These spicules exhibit a unique concentric layering structure, which contributes to their exceptional mechanical resistance. In this study, finite element method simulations were used to comprehensively investigate the effect of nested cylindrical structures on the mechanical properties of spicules. This investigation leveraged scanning electron microscopy images to guide the computational modeling of the microstructure and the results were validated by three-point bending tests of 3D-printed spicule-inspired structures. The numerical analyses showed that the nested structure of spicules induces stress and strain jumps on the layer interfaces, reducing the load on critical zones of the fiber and increasing its toughness. It was found that this effect shows a tapering enhancement as the number of layers increases, which combines with a threshold related to the 3D-printing manufacturability to suggest a compromise for optimal performance. A comprehensive evaluation of the mechanical properties of these fibers can assist in developing a new generation of bioinspired structures with practical real-world applications.

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嵌套结构在小刺启发纤维机械反应中的作用

Euplectella aspergillum 海洋海绵体以其卓越的强度和韧性而闻名。这些海绵体呈现出独特的同心分层结构，这也是其具有超凡机械阻力的原因。本研究采用有限元法模拟全面研究了嵌套圆柱结构对海绵体机械性能的影响。这项研究利用扫描电子显微镜图像来指导微观结构的计算建模，并通过三维打印尖晶石启发结构的三点弯曲测试来验证结果。数值分析表明，尖晶石的嵌套结构会在层界面上产生应力和应变跳跃，从而降低纤维临界区的载荷并提高其韧性。研究发现，随着层数的增加，这种效应会逐渐增强，这与三维打印可制造性相关的阈值相结合，提出了实现最佳性能的折衷方案。全面评估这些纤维的机械性能有助于开发新一代生物启发结构，并在现实世界中得到实际应用。

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来源期刊

Bioinspiration & Biomimetics 工程技术-材料科学：生物材料

CiteScore

5.90

自引率

14.70%

发文量

132

审稿时长

3 months

期刊介绍： Bioinspiration & Biomimetics publishes research involving the study and distillation of principles and functions found in biological systems that have been developed through evolution, and application of this knowledge to produce novel and exciting basic technologies and new approaches to solving scientific problems. It provides a forum for interdisciplinary research which acts as a pipeline, facilitating the two-way flow of ideas and understanding between the extensive bodies of knowledge of the different disciplines. It has two principal aims: to draw on biology to enrich engineering and to draw from engineering to enrich biology. The journal aims to include input from across all intersecting areas of both fields. In biology, this would include work in all fields from physiology to ecology, with either zoological or botanical focus. In engineering, this would include both design and practical application of biomimetic or bioinspired devices and systems. Typical areas of interest include: Systems, designs and structure Communication and navigation Cooperative behaviour Self-organizing biological systems Self-healing and self-assembly Aerial locomotion and aerospace applications of biomimetics Biomorphic surface and subsurface systems Marine dynamics: swimming and underwater dynamics Applications of novel materials Biomechanics; including movement, locomotion, fluidics Cellular behaviour Sensors and senses Biomimetic or bioinformed approaches to geological exploration.