Multifunctional Energy-Integrated Devices

IF 6.4 3区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Guozhen Shen, Thierry Djenizian, Zhiyong Fan, Hyunhyub Ko, Cunjiang Yu
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The topics covered in this special issue tackle the aforementioned challenges from different angles spanning materials, mechanisms, devices, and systems as a whole, paving the way to the development of next-generation self-powered, wearable, and smart devices.</p><p>In this special issue, Djenizian and co-workers report coaxial wire-shaped Li-ion batteries by adopting the unidirectional helical winding method, which shows high energy storage capacity while maintaining high flexibility and stretchability without compromising the electrochemical performance upon mechanical deformation (article number 2302117). Lethien and co-workers demonstrate a new class of electrolytic micro-capacitors by miniaturizing an electrolytic capacitor based on tantalum materials, yielding good capacitance retention of over 90% upon cycling 300 000 times (article number 2400682). Wu and co-workers have designed a simple hydrothermal strategy to pre-intercalate gallium ions in vanadate electrodes for aqueous Zn batteries. The reported device shows high specific capacity and energy density, in addition to good cycling performance and stability upon bending (article number 2400125). These research results demonstrate effective strategies for advancing the frontiers of energy storage research, particularly of interest to portable and miniaturized applications. Park and co-workers review the prospects and challenges in the field of battery-integrated systems, highlighting the need for advancements in energy density, power output, and safety to meet the demands of modern electronics (article number 2302236).</p><p>Progress on energy harvesting devices is also a focus of this special issue. Dahiya and co-workers present 315 um<sup>2</sup>-sized miniaturized photovoltaic microcells made of roll-printed nanoscale photoactive electronic layers. By interconnecting 32 microcells in parallel, indoor light harvesting under white LED illumination has been realized (article number 2400728). Roy and co-workers report a composite-engineered thermoelectric module for high-efficiency waste heat recovery (article number 2301722). Chen and co-workers demonstrate a thermoelectric-water hybrid cooling garment that displays effective cooling along with a high coefficient of performance while maintaining thermal comfort (article number 2301069). Di and co-workers review advances in organic thermoelectric devices with particular focus on energy harvesting and sensing applications (article number 2302128). Hu and co-workers discuss progress in textile triboelectric nanogenerators which has enabled the rapid development of wearable energy-integrated technologies, leading to lightweight, low-cost, flexible, stretchable, washable, and smart energy-integrated devices (article number 2302012).</p><p>Six original research articles on sensory devices with diverse functionalities and their integrated systems are also collected in this special issue. Dong and co-workers report a mechanoluminescent material for accurate stress visualization and pioneer its use in security labels (article number 2301948). Nielsch and co-workers establish a thin film approach to develop photodetectors with improved sensitivity, showing great potential in optoelectronic applications (article number 2302049). Kim and co-workers demonstrate an implantable ultrasound-driven triboelectric nanogenerator of exceptional stability and acoustic impedance compatibility with human-like tissues. 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引用次数: 0

Abstract

The era of Internet of Things has been driving the rapid development of multifunctional devices featuring the seamless integration of modules of energy, sensing, actuation, displays, etc., towards miniaturized devices and smart applications in fields as diverse as robotics, medicine, and space exploration. However, challenges such as incompatibilities between different functioning subunits, which inevitably cause compromised performance, distant or wire connections that lead to a poor level of integration and power loss, etc., demand immediate solutions. Moreover, core to any electronic applications, future power sources require new strategies to realize the combination of high energy density, security, ultralight weight, and small size.

This special issue is a collection of 12 research articles and 11 review articles, contributed by renowned researchers in the field of multifunctional energy-integrated devices. The articles can be sorted into three themes: 1) advanced energy storage devices, including batteries and supercapacitors; 2) energy harvesting devices, including photovoltaic cells, thermoelectric devices, and triboelectric nanogenerators; 3) multifunctional devices that integrate energy harvesting and storage for optoelectronic and biological sensory systems. The topics covered in this special issue tackle the aforementioned challenges from different angles spanning materials, mechanisms, devices, and systems as a whole, paving the way to the development of next-generation self-powered, wearable, and smart devices.

In this special issue, Djenizian and co-workers report coaxial wire-shaped Li-ion batteries by adopting the unidirectional helical winding method, which shows high energy storage capacity while maintaining high flexibility and stretchability without compromising the electrochemical performance upon mechanical deformation (article number 2302117). Lethien and co-workers demonstrate a new class of electrolytic micro-capacitors by miniaturizing an electrolytic capacitor based on tantalum materials, yielding good capacitance retention of over 90% upon cycling 300 000 times (article number 2400682). Wu and co-workers have designed a simple hydrothermal strategy to pre-intercalate gallium ions in vanadate electrodes for aqueous Zn batteries. The reported device shows high specific capacity and energy density, in addition to good cycling performance and stability upon bending (article number 2400125). These research results demonstrate effective strategies for advancing the frontiers of energy storage research, particularly of interest to portable and miniaturized applications. Park and co-workers review the prospects and challenges in the field of battery-integrated systems, highlighting the need for advancements in energy density, power output, and safety to meet the demands of modern electronics (article number 2302236).

Progress on energy harvesting devices is also a focus of this special issue. Dahiya and co-workers present 315 um2-sized miniaturized photovoltaic microcells made of roll-printed nanoscale photoactive electronic layers. By interconnecting 32 microcells in parallel, indoor light harvesting under white LED illumination has been realized (article number 2400728). Roy and co-workers report a composite-engineered thermoelectric module for high-efficiency waste heat recovery (article number 2301722). Chen and co-workers demonstrate a thermoelectric-water hybrid cooling garment that displays effective cooling along with a high coefficient of performance while maintaining thermal comfort (article number 2301069). Di and co-workers review advances in organic thermoelectric devices with particular focus on energy harvesting and sensing applications (article number 2302128). Hu and co-workers discuss progress in textile triboelectric nanogenerators which has enabled the rapid development of wearable energy-integrated technologies, leading to lightweight, low-cost, flexible, stretchable, washable, and smart energy-integrated devices (article number 2302012).

Six original research articles on sensory devices with diverse functionalities and their integrated systems are also collected in this special issue. Dong and co-workers report a mechanoluminescent material for accurate stress visualization and pioneer its use in security labels (article number 2301948). Nielsch and co-workers establish a thin film approach to develop photodetectors with improved sensitivity, showing great potential in optoelectronic applications (article number 2302049). Kim and co-workers demonstrate an implantable ultrasound-driven triboelectric nanogenerator of exceptional stability and acoustic impedance compatibility with human-like tissues. They have further validated consistent voltage generation and nerve stimulation capabilities (article number 2400317). Ni and co-workers report a flexible micro-supercapacitor made of anthracite-based porous carbon, showing consistent and stable signal output as a strain sensor (article number 2301523). Zhu and co-workers also report a supercapacitor for wearable self-powered smart sensors. The supercapacitor is made of Ni-Co layered double hydroxide, and can be used to monitor copper ions in sweat (article number 2400163). Apart from functional materials and devices, fabrication and architecture are equally important, especially for the applications of non-planar and wearable electronics. In this regard, Zheng et al. have developed an electrochemical replication and transfer method to realize 3D patterning, providing a high-throughput and low-cost approach to fabricating high Figure of Merit (over 30000) flexible transparent electrodes (article number 2301695).

The final eight articles are Reviews with a particular focus on function integration and self-powered systems, and comprehensively discuss advances and challenges in this field. Galstyan and co-workers review recent advances in self-powered electrochemical biosensors for early diagnosis of diseases (article number 2400395). Han and co-workers introduce recent progress in wearable self-powered biomechanical sensors towards cardiovascular system monitoring, acoustic signal detection, human motion tracking, etc. (article number 2301895). Lan and co-workers elaborate on progress in the integration of supercapacitors with sensors and energy-harvesting devices (article number 2301796). Yi and co-workers put further emphasis on flexible supercapacitor integrated systems (article number 2301931). Li and co-workers discuss the latest research on various methods of harvesting human body energy and related wearable parts, focusing on new materials, structures, and processes (article number 2302068). Mo and co-workers examine advanced electrochromic energy storage devices based on conductive polymers that merge the dual functions of energy storage and display, with great potential for use in wearable and portable devices (article number 2301969). Wen and co-workers report on recent progress in self-powered pressure sensors for the Internet of Healthcare (article number 2301480). Zhang and co-workers highlight advances in bioinspired soft robots from the point of view of fabrication, actuation, locomotion, and tracking, towards applications such as vessel recanalization, targeted drug delivery, and cargo manipulation (article number 2301862).

We thank all the authors in this special issue for their valuable contributions to this area of applied research. We also appreciate the input of other experts who have volunteered their expertise and time during the peer review process. We are especially grateful to the Advanced Materials Technologies Editorial Office for their efforts in making this special issue possible.

The papers in this special issue span a variety of important and interesting topics on multifunctional devices enabled by seamlessly integrating energy power sources with other functional components. We hope that this collection of articles informs and stimulates further research on this specific topic towards next-generation miniaturized and wearable electronics, promoting their practical use in important fields such as healthcare, biology, and robotics.

The authors declare no conflict of interest.

多功能能源集成设备
物联网时代推动了多功能设备的快速发展,这些设备将能源、传感、驱动、显示等模块无缝集成,实现了设备的微型化,并在机器人、医疗和太空探索等不同领域实现了智能应用。然而,不同功能子单元之间的不兼容性不可避免地会影响性能,远距离连接或线缆连接会导致集成度低和功率损耗等问题,这些挑战都需要立即得到解决。此外,作为任何电子应用的核心,未来的电源需要新的策略来实现高能量密度、安全性、超轻重量和小尺寸的结合。本特刊汇集了 12 篇研究文章和 11 篇评论文章,由多功能能源集成器件领域的知名研究人员撰写。文章可分为三个主题:1)先进的能量存储设备,包括电池和超级电容器;2)能量收集设备,包括光伏电池、热电设备和三电纳米发电机;3)光电和生物传感系统的能量收集和存储一体化多功能设备。在本特刊中,Djenizian 和合作者报告了采用单向螺旋缠绕法的同轴线形锂离子电池,该电池在保持高柔性和可拉伸性的同时,在机械变形时不会影响电化学性能,从而显示出较高的储能能力(文章编号 2302117)。Lethien 及其合作者通过微型化基于钽材料的电解电容器,展示了一类新型电解微型电容器,在循环 30 万次后电容保持率超过 90%(文章编号 2400682)。Wu 及其合作者设计了一种简单的水热法策略,在钒酸盐电极中预夹层镓离子,用于水性锌电池。所报告的装置显示出高比容量和能量密度,以及良好的循环性能和弯曲稳定性(文章编号 2400125)。这些研究成果展示了推进储能研究前沿的有效策略,尤其是对便携式和微型化应用具有重要意义。Park 和合作者回顾了电池集成系统领域的前景和挑战,强调了提高能量密度、功率输出和安全性以满足现代电子产品需求的必要性(文章编号 2302236)。Dahiya 及其合作者展示了 315 um2 大小的微型光伏微电池,这些微电池由滚动印刷的纳米级光活性电子层制成。通过将 32 个微电池并行互连,实现了在白色 LED 照明下的室内采光(文章编号 2400728)。Roy 及其合作者报告了一种用于高效废热回收的复合工程热电模块(文章编号 2301722)。Chen 及其合作者展示了一种热电-水混合冷却服装,该服装在保持热舒适度的同时,还能显示出有效的冷却效果和较高的性能系数(文章编号 2301069)。Di 及其合作者回顾了有机热电器件的进展,尤其关注能量收集和传感应用(文章编号 2302128)。Hu 和合作者讨论了纺织品三电纳米发电机的进展,该技术促进了可穿戴能源集成技术的快速发展,带来了轻质、低成本、灵活、可拉伸、可清洗的智能能源集成设备(文章编号 2302012)。Dong 及其合作者报告了一种用于准确显示应力的机械发光材料,并率先将其用于安全标签(文章编号 2301948)。Nielsch 及其合作者采用薄膜方法开发出灵敏度更高的光电探测器,显示出光电应用的巨大潜力(文章编号 2302049)。Kim 及其合作者展示了一种可植入的超声波驱动三电纳米发电机,它具有卓越的稳定性和与类人组织的声阻抗兼容性。他们进一步验证了一致的电压产生和神经刺激能力(文章编号 2400317)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Advanced Materials Technologies
Advanced Materials Technologies Materials Science-General Materials Science
CiteScore
10.20
自引率
4.40%
发文量
566
期刊介绍: Advanced Materials Technologies Advanced Materials Technologies is the new home for all technology-related materials applications research, with particular focus on advanced device design, fabrication and integration, as well as new technologies based on novel materials. It bridges the gap between fundamental laboratory research and industry.
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