Biomimetic Micro/Nano-structured Adhesive Materials with "Smart" Properties

具有“智能”特性的仿生微纳结构粘合材料

• 批准号: RGPIN-2014-04663
• 负责人: Zhao, Boxin
• 金额: $ 2.55万
• 依托单位: University of Waterloo
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=587942
• 关键词: Biomimetic; Micro; Nano; structured; Adhesive

With the rapidly growing demand to miniaturize machines and maximize their performance density, the effective adhesion and/or joining of similar and dissimilar material components has become one of the most critical technical prerequisites for manufacturing biosensors, medical devices, microelectronics and many other technologies at ever-smaller scales, where other means of materials joining (e.g., bolts-nuts, fastening, welding) do not work effectively. The proposed program of research aims at the development of biomimetic micro and nano-structured adhesive materials with smart properties for next-generation advanced materials and manufacturing processes. Inspired by the superior properties and structures of biological systems, such as lotus superhydrophobic anti-adhesive leaves and gecko adhesive toe pads, in the current Discovery Grant program, my research team has developed several generations of biomimetic micro-structures and used them to tailor adhesion and associated interfacial phenomena, such as wetting, deformation, and cracking at interface between materials. We also developed various nanoscale materials and acquired a deep understanding of viscoelastic behavior of polymer adhesives and nanoscale surface interactions. Building on the previous successes, the proposed program will further develop this exciting biomimetic field by extending recent advances in nanotechnology and nanoscience to develop a new generation of biomimetic adhesives with multifunctional "smart" properties. Based on our own research findings and literature reports, we have developed a new concept of using functional nanocomposite materials in the biomimetic adhesive structures; the interplay among the electrically conductive nanofillers and their interaction with the polymer matrix will make the nanocomposite biomimetic adhesive structures possible to deliver multifunctional “smart” properties. A nice niche of application of our adhesive research in electronic manufactures has been established. We will focus on such smartness as electrical conductivity, piezoelectric responses and adhesion adaptation. Nanoscale functional fillers (e.g. silver) will be incorporated into the biomimetic structures to make them electrically conductive so as to deliver such “smart” functions as piezoelectric and sensing properties to adhesive materials. These smart biomimetic structures will be functionalized with advanced chemistry to make it have adaptable adhesion to challenging surfaces. For example, Geckos are well adapted to both dry and wet conditions; but current gecko mimics lack this adaptability and limits its applications in humid and wet conditions. Under the proposed project, new types of hydrogel-like thin films will be synthesized and utilized to functionalize the adhesive structures so that they can have the desired adaptable adhesion properties. Similar to surface proteins on the gecko foot pad, the surface polymer gel have the ability to response to changes in environmental conditions. Furthermore, this research will explore ways to transfer the developed technology and mechanistic understanding into effective adhesion and bonding processes used in biological and mechanical systems’ applications. Overall, the proposed research program is at the forefront of the field of bionanomaterials and provides excellent training opportunities for graduate students. The planned research activities are original and innovative, likely leading to revolutionary advances that will have a broad impact to the scientific community. This program will help maintain the competitive advantage of Canadian scientific community and manufacturing industries and benefit mankind as well.

随着机器小型化和性能密度最大化的需求迅速增长，相似和不同材料组件的有效粘附和/或连接已成为制造生物传感器、医疗设备、微电子和许多其他技术的最关键技术先决条件之一，在这些技术中，其他材料连接方式（例如螺栓-螺母、紧固、焊接）无法有效工作。该研究计划旨在开发具有智能性能的仿生微纳米结构粘合材料，用于下一代先进材料和制造工艺。受到生物系统的优越性能和结构的启发，例如莲花超疏水抗粘叶子和壁虎粘趾垫，在当前的发现资助项目中，我的研究团队开发了几代仿生微结构，并使用它们来定制粘附和相关的界面现象，例如材料之间的润湿，变形和开裂界面。我们还开发了各种纳米级材料，并对聚合物粘合剂的粘弹性行为和纳米级表面相互作用有了深入的了解。在先前成功的基础上，拟议的项目将进一步发展这一令人兴奋的仿生领域，通过扩展纳米技术和纳米科学的最新进展，开发具有多功能“智能”特性的新一代仿生粘合剂。