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用于能量收集和软体机器人的先进材料:提升压电性能和功能的新兴前沿领域。

Advanced Materials for Energy Harvesting and Soft Robotics: Emerging Frontiers to Enhance Piezoelectric Performance and Functionality.

作者信息

Persano Luana, Camposeo Andrea, Matino Francesca, Wang Ruoxing, Natarajan Thiyagarajan, Li Qinlan, Pan Min, Su Yewang, Kar-Narayan Sohini, Auricchio Ferdinando, Scalet Giulia, Bowen Chris, Wang Xudong, Pisignano Dario

机构信息

NEST, Istituto Nanoscienze-CNR and Scuola Normale Superiore, Pisa, I-56127, Italy.

Department of Materials Science and Engineering, University of Wisconsin-Madison, Madison, 53707, USA.

出版信息

Adv Mater. 2024 Nov;36(45):e2405363. doi: 10.1002/adma.202405363. Epub 2024 Sep 18.

DOI:10.1002/adma.202405363
PMID:39291876
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11543516/
Abstract

Piezoelectric energy harvesting captures mechanical energy from a number of sources, such as vibrations, the movement of objects and bodies, impact events, and fluid flow to generate electric power. Such power can be employed to support wireless communication, electronic components, ocean monitoring, tissue engineering, and biomedical devices. A variety of self-powered piezoelectric sensors, transducers, and actuators have been produced for these applications, however approaches to enhance the piezoelectric properties of materials to increase device performance remain a challenging frontier of materials research. In this regard, the intrinsic polarization and properties of materials can be designed or deliberately engineered to enhance the piezo-generated power. This review provides insights into the mechanisms of piezoelectricity in advanced materials, including perovskites, active polymers, and natural biomaterials, with a focus on the chemical and physical strategies employed to enhance the piezo-response and facilitate their integration into complex electronic systems. Applications in energy harvesting and soft robotics are overviewed by highlighting the primary performance figures of merits, the actuation mechanisms, and relevant applications. Key breakthroughs and valuable strategies to further improve both materials and device performance are discussed, together with a critical assessment of the requirements of next-generation piezoelectric systems, and future scientific and technological solutions.

摘要

压电能量采集可从多种来源捕获机械能,如振动、物体和身体的运动、冲击事件以及流体流动,以产生电能。这种电力可用于支持无线通信、电子元件、海洋监测、组织工程和生物医学设备。针对这些应用,已经生产出了各种自供电压电传感器、换能器和致动器,然而,提高材料的压电性能以提升器件性能的方法仍然是材料研究中一个具有挑战性的前沿领域。在这方面,可以对材料的固有极化和特性进行设计或有意调控,以增强压电产生的功率。本综述深入探讨了先进材料(包括钙钛矿、活性聚合物和天然生物材料)中的压电机制,重点关注用于增强压电响应并促进其集成到复杂电子系统中的化学和物理策略。通过突出主要性能指标、驱动机制和相关应用,对能量采集和软体机器人领域的应用进行了概述。讨论了进一步提高材料和器件性能的关键突破和有价值的策略,同时对下一代压电系统的要求进行了批判性评估,并探讨了未来的科学技术解决方案。

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3
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Molecules. 2025 Jan 4;30(1):179. doi: 10.3390/molecules30010179.
4
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Nat Commun. 2024 Jan 27;15(1):819. doi: 10.1038/s41467-024-45184-4.
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Nat Commun. 2023 Oct 17;14(1):6562. doi: 10.1038/s41467-023-42184-8.
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