Carbon Nanotubes: Building Blocks for Power Textiles

碳纳米管：动力纺织品的基础材料

• 批准号: RGPIN-2017-04295
• 负责人: Koleilat, Ghada
• 金额: $ 1.75万
• 依托单位: Dalhousie University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=655822
• 关键词: Carbon; Nanotubes; Building; Blocks; Power

According to the US National Renewable Energy Rooftop solar energy has the potential to deliver 39% of the US energy demand using current solar technology; in fact, if we convert the radiant solar energy hitting the earth's surface for only one hour, we would meet the world's yearly energy demand. However, largely around the world, the present cost of standard photovoltaic modules based on crystalline silicon technology is not competitive enough to replace the dominant but slowly depleting fossil fuels resources. Canada needs to develop a solar technology that is at the same time efficient and low in cost. ***Furthermore, wearable technology in health monitoring, and entertainment have led to high-tech applications and are growing at an exponential pace. With today's society needs in mind, wearable devices must survive vigorous external stresses caused by flexing, twisting, stretching and exposure to random conditions. Rigid circuit boards in wearable technology are reaching the limits of their practical feasibility. ***Our research group is focusing on solution-processed semiconducting carbon nanotubes (CNTs). We propose to use this technology to address these two challenges using an innovative materials processing strategy which will allow CNT's to be used as building blocks for low cost high efficiency photovoltaics that can be fully integrated as a power source in textiles, i.e. power textiles. ***The properties of CNTs are highly dependent on the direction and the degree of twist they are wrapped in and are thus extremely tunable. CNTs can either be metallic or semiconducting, with their bandgap ranging from 0 to 2 eV. With just as little as 80 nm thick films, CNTs can absorb the entirety of the sun's radiation spectrum. In addition to their exceptional electrical, and optical properties, CNTs possess unmatched mechanical properties. We believe that we are well placed to be the first to fabricate a highly efficient scalable carbon nanotube based solar junction. We also plan to leverage the mechanical compliance of carbon nanotubes for the first time to fabricate the first scalable textile-integrated photovoltaic junction, i.e. power textiles. ***This project will generate scientific insights on the potential of carbon nanotubes in light conversion applications and will lead to innovations in the field of solar energy and wearable electronics. It will support 7 highly qualified personnel who will be trained in an inclusive interdisciplinary environment with potential international collaboration.

根据美国国家可再生能源屋顶太阳能有潜力提供39%的美国能源需求使用目前的太阳能技术;事实上，如果我们转换辐射太阳能击中地球表面只有一个小时，我们将满足世界每年的能源需求。然而，在世界范围内，基于晶体硅技术的标准光伏模块的当前成本不足以取代占主导地位但正在缓慢耗尽的化石燃料资源。加拿大需要开发一种既高效又低成本的太阳能技术。* 此外，健康监测和娱乐领域的可穿戴技术已导致高科技应用，并以指数级速度增长。考虑到当今社会的需求，可穿戴设备必须能够承受由弯曲、扭曲、拉伸和暴露于随机条件引起的强烈外部应力。可穿戴技术中的刚性电路板正在达到其实际可行性的极限。* 我们的研究小组专注于溶液处理的半导体碳纳米管（CNT）。我们建议使用这种技术来解决这两个挑战，使用一种创新的材料加工策略，这将允许CNT被用作低成本高效率光致发光器件的构建模块，其可以完全集成为纺织品中的电源，即电力纺织品。* 碳纳米管的性能高度依赖于它们缠绕的方向和扭曲程度，因此非常可调。CNT可以是金属的或半导体的，其带隙范围为0至2 eV。只有80纳米厚的薄膜，碳纳米管可以吸收整个太阳辐射光谱。除了其卓越的电学和光学性能外，CNT还具有无与伦比的机械性能。我们相信，我们有能力成为第一个制造高效可扩展的碳纳米管太阳能结的公司。我们还计划首次利用碳纳米管的机械顺应性来制造第一个可扩展的纺织品集成光伏结，即电力纺织品。*** 该项目将对碳纳米管在光转换应用中的潜力产生科学见解，并将导致太阳能和可穿戴电子领域的创新。它将支持7名高素质人员，他们将在具有潜在国际合作的包容性跨学科环境中接受培训。