Stretchable, flexible and transparent electronic materials

可拉伸、柔性、透明的电子材料

• 批准号: RGPIN-2017-06319
• 负责人: Cicoira, Fabio
• 金额: $ 2.7万
• 依托单位: École Polytechnique de Montréal
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=687019
• 关键词: Stretchable; flexible; transparent; electronic; materials

Flexible, stretchable and transparent electronic materials are playing a central role in a myriad of novel applications that are expected to become ubiquitous in our society, such as artificial muscles and skin, smart textiles, biomedical devices, prosthetics and flexible displays. Progress in electronics for these new fields comes after decades of intense research and development in materials science, which have resulted in materials combining properties that are often mutually exclusive. For instance, materials showing high mechanical compliance, conductivity and transparency are now a reality. ******Enormous attention is being paid nowadays to two classes of materials that are very attractive for flexible, stretchable and transparent electronics: organic conducting polymers and metal oxide semiconductors. Both types of materials offer the opportunity to deposit transparent films using low-cost, solution-based techniques on a variety of substrates. A wide range of devices employ conducting polymers and semiconducting metal oxides as the electroactive materials. These include transistors, light-emitting diodes, biomedical devices, and chemical and mechanical sensors. ******In spite of this progress, we face many challenges before we can fully exploit the potential of these materials for flexible, stretchable and transparent electronics. A particularly desirable property for conducting polymers, especially for applications in bioelectronics, would be the ability to self-repair damage. This would permit, for instance, implanted devices capable to work under harsh mechanical conditions without need for frequent replacement. Another challenging issue is the ability to pattern conducting polymer devices with high spatial resolution on unconventional substrates, such as elastomers. For metal oxides, although gallium indium zinc oxide (IGZO) is already used in the display industry, there is a need to find elements more abundant than In and Ga, which can be processed with low-cost, solution-based techniques. ******The objective of this Discovery Research Program is: developing disruptive technologies for self-healing electronic materials, flexible/stretchable electronic devices and metal oxide electronics, with applications in wearable electronics, bioelectronics and transparent electronics, and providing a fundamental understanding of the phenomena controlling the electrical and mechanical properties of these materials and devices. Our work will include materials processing and patterning, device fabrication and advanced exploration of fundamental properties of materials. ******Because of its multidisciplinary character, its potential to produce high-impact science and innovative technology, this Research Program represents an exceptional opportunity to train highly qualified personnel, to respond to the scientific and technological challenges of our society.

柔性、可拉伸和透明的电子材料在无数新的应用中发挥着核心作用，这些应用预计将在我们的社会中无处不在，例如人造肌肉和皮肤、智能纺织品、生物医学设备、假肢和柔性显示器。这些新领域的电子学进展是在材料科学数十年的密集研究和开发之后取得的，这些研究和开发导致材料结合了通常相互排斥的特性。例如，显示出高机械顺应性、导电性和透明度的材料现在已经成为现实。** 如今，人们对两类材料给予了极大的关注，这两类材料对于柔性、可拉伸和透明的电子产品非常有吸引力：有机导电聚合物和金属氧化物半导体。这两种类型的材料都提供了使用低成本、基于溶液的技术在各种基板上存款透明膜的机会。广泛的器件采用导电聚合物和半导电金属氧化物作为电活性材料。这些包括晶体管、发光二极管、生物医学设备以及化学和机械传感器。** 尽管取得了这些进展，但在我们能够充分利用这些材料用于柔性，可拉伸和透明电子产品之前，我们还面临着许多挑战。对于导电聚合物，特别是对于生物电子学中的应用，一个特别期望的性质将是自修复损伤的能力。例如，这将允许植入装置能够在苛刻的机械条件下工作而无需频繁更换。另一个具有挑战性的问题是在非常规基底（例如弹性体）上以高空间分辨率图案化导电聚合物器件的能力。对于金属氧化物，虽然镓铟锌氧化物（IGZO）已经用于显示器行业，但需要找到比In和Ga更丰富的元素，其可以用低成本的基于溶液的技术进行处理。 ** 本发现研究计划的目标是：开发用于自修复电子材料，柔性/可伸缩电子器件和金属氧化物电子器件的颠覆性技术，并应用于可穿戴电子器件，生物电子器件和透明电子器件，并提供对控制这些材料和器件的电气和机械特性的现象的基本理解。我们的工作将包括材料加工和图案化，器件制造和材料基本特性的高级探索。* 由于其多学科性质，其产生高影响力的科学和创新技术的潜力，该研究计划代表了培养高素质人才的绝佳机会，以应对我们社会的科学和技术挑战。