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https://doi.org/10.1021/acsami.2c19456
Title: | New Class of Multifunctional Bioinspired Microlattice with Excellent Sound Absorption, Damage Tolerance, and High Specific Strength | Authors: | Li, Zhendong Wang, Xinxin Li, Xinwei Wang, Zhonggang Zhai, Wei |
Keywords: | Science & Technology Technology Nanoscience & Nanotechnology Materials Science, Multidisciplinary Science & Technology - Other Topics Materials Science microlattice metamaterials bioinspired materials sound absorption damage tolerance high strength MECHANICAL RESPONSE LATTICE METAMATERIALS |
Issue Date: | 19-Jan-2023 | Publisher: | AMER CHEMICAL SOC | Citation: | Li, Zhendong, Wang, Xinxin, Li, Xinwei, Wang, Zhonggang, Zhai, Wei (2023-01-19). New Class of Multifunctional Bioinspired Microlattice with Excellent Sound Absorption, Damage Tolerance, and High Specific Strength. ACS APPLIED MATERIALS & INTERFACES 15 (7). ScholarBank@NUS Repository. https://doi.org/10.1021/acsami.2c19456 | Abstract: | Although mutually independent, simultaneous sound absorption and superior mechanical properties are often sought after in a material. One main challenge in achieving such a material will be on how to design it. Herein, we propose a bamboo-inspired design strategy to overcome the aforementioned challenges. Building on top of the basic octet-truss design, we introduce a hollow-tube architecture to achieve lightweight property and mechanical robustness and a septum-chamber architecture to introduce acoustic resonant cells. The concept is experimentally verified through samples fabricated using selective laser melting with the Inconel 718 alloy. High sound absorption coefficients (>0.99) with broadband spectra, damage-tolerant behavior, high specific strength (up to 81.2 MPa·cm3/g), and high specific energy absorption of 40.1 J/g have been realized in this design. The sound absorption capability is attributed to Helmholtz resonance through the pore-and-cavity morphology of the structure. Microscopically speaking, dissipation primarily occurs via the viscous frictional flow and thermal boundary layers on the air and microlattice interactions at the narrow pores. The high strength is in turn attributed to the near-membrane state of stress in the plate structures and the excellent strength of the base material. Overall, this work presents a new design concept for developing multifunctional metamaterials. | Source Title: | ACS APPLIED MATERIALS & INTERFACES | URI: | https://scholarbank.nus.edu.sg/handle/10635/243347 | ISSN: | 1944-8244 1944-8252 |
DOI: | 10.1021/acsami.2c19456 |
Appears in Collections: | Staff Publications Elements |
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