摘要
柔性可穿戴电子设备因其在人工智能、健康医疗等领域的应用而受到了人们的极大关注.然而,如何降低功耗或实现自供能一直是阻碍其广泛应用的瓶颈.随着纳米发电机与自驱动技术的兴起,尤其以摩擦纳米发电机(TENG)与压电纳米发电机(PENG)代表的研究,为解决可穿戴传感器电源的问题提供了可行的方案.TENG和PENG分别基于摩擦起电效应与压电效应,可以将机械能转化为电能,同时具备可拉伸性、生物相容性和自愈性等优良特性,已经广泛应用于自驱动的触觉传感器的设计制备中,并作为下一代可穿戴电子设备的技术基础展现出巨大的应用潜力.基于该领域的最新进展,本文对TENG与PENG的机理进行概述,对其性能优化途径进行归纳,再结合材料、器件的设计等讨论应力应变与分布、滑移等纳米发电机自驱动传感器的制备与应用研究.最后,对自驱动触觉传感器目前存在的问题与挑战进行讨论,并对未来的发展进行展望.
With the advance of the fourth industrial revolution,a wave of emerging industries and interdisciplinary research is breaking out,such as the Internet of Things,megadata,humanoid robots and artificial intelligence.The rapid development of these functional electronic devices is changing the way people communicate with each other and their surroundings,thus integrating our world into an intelligent information network.The applications of flexible wearable electronic devices in intelligent robots,health and medical monitoring and other fields have attracted great attention.Following the human skin,the device can respond to external stimuli and should also have stretchability and self-healing properties.In practical applications,a large network of sensors is needed to connect with humans or robots,so the supply of energy is crucial.Several forms of green and renewable energy have been searched for,such as magnetic energy,solar energy,thermal energy,mechanical energy and microbial chemical energy.However,high cost,limitations in the choice of materials,and other disadvantages have become serious bottlenecks.The advent of nanogenerator brings a novel and effective solution to the above problems.Here in this work,the triboelectronic nanogenerator(TENG)and the piezoelectric generator(PENG)are taken as two representative objectives,which are,respectively,based on the triboelectronic effect and piezoelectronic effect to realize the collection of mechanical energy,and each of them can be used as a self-power sensor,which can generate electrical signals,respond to environmental stimuli,and need no power supply any more.The optimization and design of nanogenerator is always a key factor to improve its performance and wide application.At present,the methods commonly adopted in optimization schemes mainly include material selection,design and optimization of structural layer and electrode.The selection of materials should be based on low cost,stretchability,transparency,stability and biocompatibility.Firstly,for the optimizatio
作者
王闯
鲍容容
潘曹峰
Wang Chuang;Bao Rong-Rong;Pan Cao-Feng(College of Physical Science and Engineering Technology,Guangxi University,Nanning 530004,China;Beijing Institute of Nanotechnology and Energy System,Chinese Academy of Sciences,Beijing 101400,China)
出处
《物理学报》
SCIE
EI
CAS
CSCD
北大核心
2021年第10期61-75,共15页
Acta Physica Sinica
基金
国家自然科学基金(批准号:U20A20166,61675027,61805015,61804011)
科技部重点研发专项(批准号:2016YFA0202703)
北京市自然科学基金(批准号:Z180011)
深圳市科技计划项目(批准号:KQTD20170810105439418).
关键词
纳米发电机
可穿戴电子设备
触觉传感器
柔性器件
nanogenerator
flexiblewearable electronic device
touch sensor
flexible device
