TY - JOUR
T1 - Flexible Impact-Resistant Composites with Bioinspired Three-Dimensional Solid-Liquid Lattice Designs
AU - Wang, Zhanyu
AU - Bo, Renheng
AU - Bai, Haoran
AU - Cao, Shunze
AU - Wang, Shuheng
AU - Chang, Jiahui
AU - Lan, Yu
AU - Li, Ying
AU - Zhang, Yihui
N1 - Publisher Copyright:
© 2023 American Chemical Society.
PY - 2023/5/10
Y1 - 2023/5/10
N2 - The ubiquitous solid-liquid systems in nature usually present an interesting mechanical property, the rate-dependent stiffness, which could be exploited for impact protection in flexible systems. Herein, a typical natural system, the durian peel, has been systematically characterized and studied, showing a solid-liquid dual-phase cellular structure. A bioinspired design of flexible impact-resistant composites is then proposed by combining 3D lattices and shear thickening fluids. The resulting dual-phase composites offer, simultaneously, low moduli (e.g., 71.9 kPa, lower than those of many reported soft composites) under quasi-static conditions and excellent energy absorption (e.g., 425.4 kJ/m3, which is close to those of metallic and glass-based lattices) upon dynamic impact. Numerical simulations based on finite element analyses were carried out to understand the enhanced buffering of the developed composites, unveiling a lattice-guided fluid-structure interaction mechanism. Such biomimetic lattice-based flexible impact-resistant composites hold promising potential for the development of next-generation flexible protection systems that can be used in wearable electronics and robotic systems.
AB - The ubiquitous solid-liquid systems in nature usually present an interesting mechanical property, the rate-dependent stiffness, which could be exploited for impact protection in flexible systems. Herein, a typical natural system, the durian peel, has been systematically characterized and studied, showing a solid-liquid dual-phase cellular structure. A bioinspired design of flexible impact-resistant composites is then proposed by combining 3D lattices and shear thickening fluids. The resulting dual-phase composites offer, simultaneously, low moduli (e.g., 71.9 kPa, lower than those of many reported soft composites) under quasi-static conditions and excellent energy absorption (e.g., 425.4 kJ/m3, which is close to those of metallic and glass-based lattices) upon dynamic impact. Numerical simulations based on finite element analyses were carried out to understand the enhanced buffering of the developed composites, unveiling a lattice-guided fluid-structure interaction mechanism. Such biomimetic lattice-based flexible impact-resistant composites hold promising potential for the development of next-generation flexible protection systems that can be used in wearable electronics and robotic systems.
KW - bioinspired designs
KW - durian peels
KW - flexible impact-resistant composites
KW - fluid−structure interaction
KW - shear thickening fluid (STF)
UR - http://www.scopus.com/inward/record.url?scp=85156196560&partnerID=8YFLogxK
U2 - 10.1021/acsami.3c02761
DO - 10.1021/acsami.3c02761
M3 - Article
C2 - 37098745
AN - SCOPUS:85156196560
SN - 1944-8244
VL - 15
SP - 22553
EP - 22562
JO - ACS applied materials & interfaces
JF - ACS applied materials & interfaces
IS - 18
ER -