Nanocomposites and Bio-inspired Nanostructures

纳米复合材料和仿生纳米结构

• 批准号: RGPIN-2016-05597
• 负责人: Erb, Uwe
• 金额: $ 3.13万
• 依托单位: University of Toronto
• 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=688676
• 关键词: Nanocomposites; Bio; inspired; Nanostructures

This research program is concerned with the development, characterization and property measurements of several advanced nanostructured materials that are currently not available elsewhere in the world. These include high strength and corrosion resistant nanocrystalline Cu-Ni alloys for use in marine structure repair, a new class of durable superhydrophobic metal composite coatings for application as non-wetting surfaces, high thermal conductivity Cu-diamond composites for thermal management in electronic devices and antireflective/optical surfaces based on the so-called moth eye effect. This program has a strong emphasis on smart bio-inspired materials design using examples of structures found in nature as a blueprint for new engineered materials solutions. Consequently the program has a significant research component that deals with the analysis and understanding of biological materials. By paying more attention to nature's ingenuity to solve rather complex problems, this program builds on a very successful nanomaterials technology process platform previously developed by the applicant and co-workers. This process makes nanocrystalline metals by a low temperature electrochemical reaction using aqueous solutions containing metal salts. For simple metals and some alloys this process has already been transferred to industry and successfully applied in various industries such as industrial corrosion and wear resistant coatings, environmentally benign chromium replacement, soft magnetic materials and high strength/low weight structural materials. Some of the new materials to be developed in this program will incorporate several of nature's tricks to make structures with very specific functions such as found on non-wettable leaves that are always dry and clean or insect eye structures with unique antireflection/ optical properties. ***The results of this research will provide Canadian industry with several new materials which can find application in a broad range of industries in particular in the manufacturing sector. The nanocrystalline Cu-Ni alloys are expected to have excellent mechanical and corrosion properties and will be a crucial component in future repair technologies for marine structures such as navy and merchant ships, marine renewable energy plants and offshore oil and gas platforms. The superhydrophobic metal coatings can provide self-cleaning anticorrosion and antifouling solutions, in particular for Canada's power industries, while the Cu-diamond nanocomposite are earmarked as advanced heat sink materials for electronic devices. Finally, a better understanding of the details of the moth eye structure/function and its successful reproduction could lead to better antireflective/optical devices. ***This research will contribute to the training of up to 20 highly qualified personnel in the multidisciplinary area of nanomaterials nanobiology.**

该研究项目涉及几种目前在世界其他地方无法获得的先进纳米结构材料的开发、表征和性能测量。其中包括用于海洋结构修复的高强度耐腐蚀纳米晶铜镍合金、用作非润湿表面的新型耐用超疏水金属复合涂层、用于电子设备热管理的高导热性铜金刚石复合材料以及基于所谓的蛾眼效应的抗反射/光学表面。该计划非常重视智能仿生材料设计，使用自然界中发现的结构示例作为新工程材料解决方案的蓝图。因此，该计划有一个重要的研究部分，涉及生物材料的分析和理解。通过更多地关注大自然的创造力来解决相当复杂的问题，该项目建立在申请人和同事先前开发的非常成功的纳米材料技术工艺平台的基础上。该过程使用含有金属盐的水溶液通过低温电化学反应制造纳米晶金属。 对于简单金属和某些合金，该工艺已转移到工业中，并成功应用于工业防腐耐磨涂层、环境友好的铬替代、软磁材料和高强度/轻质结构材料等各个行业。该计划中将开发的一些新材料将结合多种自然技巧来制造具有非常特定功能的结构，例如始终干燥清洁的不可润湿叶子上的结构或具有独特抗反射/光学特性的昆虫眼睛结构。 ***这项研究的结果将为加拿大工业提供几种新材料，这些材料可以在广泛的行业中得到应用，特别是在制造业。纳米晶铜镍合金预计将具有优异的机械和腐蚀性能，并将成为未来海洋结构修复技术的关键组成部分，例如海军和商船、海洋可再生能源工厂以及海上石油和天然气平台。超疏水金属涂层可以提供自清洁防腐和防污解决方案，特别是对于加拿大的电力行业，而铜-金刚石纳米复合材料被指定为电子设备的先进散热器材料。最后，更好地了解蛾眼结构/功能的细节及其成功复制可能会导致更好的抗反射/光学设备。 ***这项研究将有助于在纳米材料纳米生物学多学科领域培训多达 20 名高素质人才。**