CAREER: Functional Nano-Composit Materials: Synthetic Methodology and Applications

职业：功能纳米复合材料：合成方法和应用

• 批准号: 0847535
• 负责人: Dmitri Talapin
• 金额: $ 60.5万
• 依托单位: University of Chicago
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-02-01 至 2014-01-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0847535&HistoricalAwards=false
• 关键词: CAREER; Functional; Nano; Composit; Materials

DMR-0847535TECHNICAL SUMMARY:The project aims to develop novel nanostructured inorganic materials with programmable physical and chemical properties. The approach involves new chemistry for solution-based fabrication of inorganic functional materials from nanoscale building blocks. Specifically, functional nanostructured phases will be synthesized by combining colloidal inorganic nanomaterials (metal and semiconductor clusters, nanocrystals, nanowires, etc) and molecular metal chalcogenide complexes. Various molecular metal chalcogenide complexes, such as SnS44-, Sn2Se64-, In2Se42-, Ge4S104- will be used to completely replace original hydrocarbon surface ligands at the surface of colloidal metal and semiconductor nanostructures. After formation of a nanostructured assembly, new surface ligands will be converted into an inorganic solid, linking individual nano-building blocks into a macroscopic array of strongly electronically coupled functional modules. The project will combine the development of synthetic methodologies, detailed structural, electronic and optical characterizations of new materials and fabrication of prototype electronic and optoelectronic devices.NON-TECHNICAL SUMMARY:The project aims to develop a generalized methodology for preparation of nanostructured inorganic materials through ?modular? self-assembly of nanoscale functional building blocks. This approach may lead to a novel class of solution processed semiconductors for the applications ranging from solar cells to thermoelectric heat converters, light-emitting devices and printable electronics. The integration of research and educational components will generate broad outreach and educational activities including participation in the conceptual design and development of the Nanoscience exhibit for Chicago Museum of Science and Industry. The Museum attracts approximately 2 million visitors per year, nearly 280,000 children in school groups and youth organizations visited the Museum in 2007. Aimed at inspiring youth to consider education and careers in the physical and biological sciences, the objective of new exhibit is to convey the excitement of modern scientific research, its multidisciplinary nature, and the synergy between different areas of science and technology.

DMR-0847535技术总结：该项目旨在开发具有可编程物理和化学特性的新型纳米结构无机材料。该方法涉及新的化学方法，用于从纳米级构建块制备基于溶液的无机功能材料。具体而言，功能性纳米结构相将通过组合胶体无机纳米材料（金属和半导体簇、纳米晶体、纳米线等）和分子金属硫属化物络合物来合成。各种分子金属硫属化物络合物，如SnS 44-、Sn 2Se 64-、In 2Se 42-、Ge 4S 104-将用于完全取代胶体金属和半导体纳米结构表面处的原始烃表面配体。在形成纳米结构组装体后，新的表面配体将被转化为无机固体，将单个纳米构建块连接到强电子耦合功能模块的宏观阵列中。该项目将联合收割机的合成方法的发展，详细的结构，电子和光学表征的新材料和制造的原型电子和光电devices.NON-TECHNICAL概要：该项目的目的是开发一个通用的方法，通过制备纳米结构的无机材料？模块化？纳米级功能构建块的自组装。这种方法可能会导致一类新的解决方案处理半导体的应用范围从太阳能电池到热电热转换器，发光器件和可印刷电子产品。研究和教育组成部分的整合将产生广泛的推广和教育活动，包括参与芝加哥科学与工业博物馆纳米科学展览的概念设计和开发。该博物馆每年吸引约200万游客，2007年有近280，000名学校团体和青年组织的儿童参观了博物馆。旨在激励青年考虑物理和生物科学的教育和职业，新展览的目标是传达现代科学研究的兴奋，其多学科性质以及不同科学和技术领域之间的协同作用。