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EAGER: Combining FerroElectret NanoGenerators (FENG) with smart materials for enabling unique performance in microdevices

EAGER：将铁电驻极体纳米发电机 (FENG) 与智能材料相结合，在微型设备中实现独特的性能

基本信息

批准号：
1744273
负责人：
Nelson Sepulveda
金额：
$ 6万
依托单位：
Michigan State University
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2017
资助国家：
美国
起止时间：
2017-07-15 至 2019-06-30
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=1744273&HistoricalAwards=false
关键词：
EAGER Combining FerroElectret NanoGenerators FENG

项目摘要

AbstractNontechnical:The proposed exploratory work is aimed at merging FerroElectret Nanogenerator (FENG) and smart materials in micrometer-sized-based devices. This is expected to establish new performance theoretical limits in the operation of micro-electro-mechanical and optical systems; and to enable unprecedented functionality. The research plan is focusing on the transition of nanogenerator technologies from device development to system implementation, enabling integration in wearable electronics. The project will complete three Major ResearchTasks that cover device optimization, system integration, and validation. The overall scientific broader impact of this work is to generate knowledge that will be of significance to researchers and developers in the fields of large-scale integration of wearable and portable systems. The societal broader impact is found in the development of an energy harvesting technology that could pave the road towards self-powering portable/wearable electronics from human motion reducing the need of non renewable energy sources.Technical:The PI's research group introduced the FENG as a promising device for harvesting energy from human motion, and demonstrated major progress in performance from the integration of single wall CNT films with vanadium dioxide (VO2)-based devices.In this early exploratory research, the PI proposes to study the feasibility of merging these two breakthroughs into micrometer-sized devices to allow for self-powering capabilities and enable touch-activated programming of electrical, mechanical, and optical states. The intellectual merit of the proposed work is found in the combination of FENG and VO2-based microdevices to enable self-powered programmable microdevices that can be integrated in wearable electronics. The potential main contributions of this exploratory research are the maturing of nanogenerator technologies capable of harvesting energy from human motion; and the development of a design platform for the integration of FENG with micrometer devices. Despite the significant progress on nanogenerators, there are still hurdles in the path towards their individual optimization and full integration with microdevices, and even more for the development of self-powered wearable electronics. The most significant obstacles that prevent the further advancement of the technology include: (i) device dynamics and frequency performance, (ii) matching impedance with power storage units, and (iii) power modulation. All these three obstacles will be addressed in the proposed exploratory research.

摘要非技术性：拟议的探索性工作旨在将铁驻极体纳米发电机（FENG）和智能材料合并到基于微米尺寸的设备中。这有望在微机电和光学系统的操作中建立新的性能理论极限;并实现前所未有的功能。该研究计划的重点是将纳米发电机技术从设备开发过渡到系统实施，从而实现可穿戴电子产品的集成。该项目将完成三个主要研究任务，包括设备优化，系统集成和验证。这项工作的总体科学影响是产生对可穿戴和便携式系统大规模集成领域的研究人员和开发人员具有重要意义的知识。更广泛的社会影响体现在能量收集技术的发展中，该技术可以为人类运动的自供电便携式/可穿戴电子产品铺平道路，从而减少对不可再生能源的需求。技术：PI的研究小组介绍了FENG作为一种有前途的从人体运动中收集能量的设备，并展示了单壁CNT薄膜与二氧化钒（VO 2）基设备集成的性能方面的重大进展。在这项早期探索性研究中，PI建议研究将这两个突破合并到微米尺寸的设备中的可行性，以允许自供电能力，并实现电、机械和光学状态的触摸激活编程。所提出的工作的智力价值是在FENG和基于VO 2的微器件的组合中发现的，以实现可以集成在可穿戴电子设备中的自供电可编程微器件。这项探索性研究的潜在主要贡献是能够从人体运动中收集能量的纳米发电机技术的成熟;以及FENG与微米设备集成的设计平台的开发。尽管纳米发电机取得了重大进展，但在实现其单独优化和与微型设备完全集成的道路上仍然存在障碍，而自供电可穿戴电子产品的开发则更加困难。阻碍该技术进一步发展的最重要障碍包括：（i）设备动态和频率性能，（ii）与功率存储单元匹配的阻抗，以及（iii）功率调制。所有这三个障碍都将在拟议的探索性研究中加以解决。