Decorated bacteria-cellulose ultrasonic metasurface

Li, Zong-Lin; Chen, Kun; Li, Fei; Shi, Zhi-Jun; Sun, Qi-Li; Li, Peng-Qi; Peng, Yu-Gui; Huang, Lai-Xin; Yang, Guang; Zheng, Hairong; Zhu, Xue-Feng

doi:10.1038/s41467-023-41172-2

Nat Commun

2023

DOI: 10.1038/s41467-023-41172-2

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Decorated bacteria-cellulose ultrasonic metasurface

Zong-Lin Li,

Kun Chen,

Fei Li

et al.

Abstract: Cellulose, as a component of green plants, becomes attractive for fabricating biocompatible flexible functional devices but is plagued by hydrophilic properties, which make it easily break down in water by poor mechanical stability. Here we report a class of SiO2-nanoparticle-decorated bacteria-cellulose meta-skin with superior stability in water, excellent machining property, ultrathin thickness, and active bacteria-repairing capacity. We further develop functional ultrasonic metasurfaces based on meta-skin p… Show more

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2024

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Cited by 20 publications

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Janus Metasurface for Underwater Sound Manipulation

Li,

Zhou,

et al. 2024

Adv Funct Materials

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Bidirectional controllable propagation of waterborne sound holds significant importance in developing multifunctional underwater acoustic and mechanical devices. However, the existing waterborne acoustic metasurfaces have rarely explored the bidirectional sound modulations. Here, a class of Janus waterborne acoustic metasurface, enabling two‐faced arbitrarily asymmetric wavefront manipulations is reported. A three‐degree‐of‐freedom mechanical system facilitated by acoustic‐structure interaction underwater is proposed to introduce bianisotropic responses of unit cells. Monolayer ultrathin Janus metasurface is inversely designed by utilizing a function‐structure integrated topology optimization framework. Distinct underwater acoustic functionalities, including axial and oblique focusing, beam splitting, and sound diffusion, are successfully demonstrated. Underwater experiments are further conducted to validate the concept of Janus metasurface. The good consistency between experimental and simulated results confirms the excellent two‐faced asymmetric acoustic focusing performance. The proposed Janus metasurface opens up a new dimension for designing advanced waterborne acoustic devices with two‐faced multifunctional wavefront manipulations.

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Janus Metasurface for Underwater Sound Manipulation

Li,

Zhou,

et al. 2024

Adv Funct Materials

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All‐in‐One: An Interwoven Dual‐Phase Strategy for Acousto‐Mechanical Multifunctionality in Microlattice Metamaterials

Li,

Zeng,

Guo

et al. 2024

Adv Funct Materials

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Multifunctional materials that integrate noise absorption, high stiffness, and isotropic elasticity are increasingly sought after for all‐in‐one applications. However, conventional microlattice metamaterials—whether truss, shell, or plate—often excel in only one property and struggle to embrace all due to structural constraints. Herein, this work presents a new additive concept—via interweaving different lattice architectures to simultaneously enhance both sound absorption and elastic properties in microlattices. The interwoven design strategy starts by analyzing a particular structure, introducing a reinforcing structure to partition air domains, compensate for local stiffness deficiencies, and improve structural integrity. As a proof of concept, the focus is on using an octet truss as the original phase and a customized truss as the reinforcing phase. The methodology enables highly customizable geometric configurations, harnessing machine learning and multi‐objective optimization to achieve superior multifunctional performance. Experimental results show that these optimized microlattices overcome traditional physical limitations, simultaneously achieve broadband sound absorption, high stiffness, and elastic isotropy. The broadband absorption results from a finely tuned over‐damped resonant response, while the remarkable elastic performance is attributed to efficient load transfer and complementary configurations. This work unveils a groundbreaking design paradigm for innovative multifunctional materials.

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Bacterial Cellulose Applications in Electrochemical Energy Storage Devices

Zheng,

Ye,

Guo

2024

Advanced Materials

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Bacterial cellulose (BC) is produced via the fermentation of various microorganisms. It has an interconnected 3D porous network structure, strong water‐locking ability, high mechanical strength, chemical stability, anti‐shrinkage properties, renewability, biodegradability, and a low cost. BC‐based materials and their derivatives have been utilized to fabricate advanced functional materials for electrochemical energy storage devices and flexible electronics. This review summarizes recent progress in the development of BC‐related functional materials for electrochemical energy storage devices. The origin, components, and microstructure of BC are discussed, followed by the advantages of using BC in energy storage applications. Then, BC‐related material design strategies in terms of solid electrolytes, binders, and separators, as well as BC‐derived carbon nanofibers for electroactive materials are discussed. Finally, a short conclusion and outlook regarding current challenges and future research opportunities related to BC‐based advanced functional materials for next‐generation energy storage devices suggestions are proposed.

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Decorated bacteria-cellulose ultrasonic metasurface

Cited by 20 publications

References 43 publications

Janus Metasurface for Underwater Sound Manipulation

Janus Metasurface for Underwater Sound Manipulation

All‐in‐One: An Interwoven Dual‐Phase Strategy for Acousto‐Mechanical Multifunctionality in Microlattice Metamaterials

Bacterial Cellulose Applications in Electrochemical Energy Storage Devices

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