GOALI: Mechanically Biased Self-Assembly of 2-D and 3-D Quantum Structures Using a Novel Nanostamping Process

GOALI：使用新型纳米冲压工艺进行 2D 和 3D 量子结构的机械偏置自组装

• 批准号: 0600511
• 负责人: Curtis Taylor
• 金额: $ 15万
• 依托单位: Virginia Commonwealth University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-08-01 至 2009-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0600511&HistoricalAwards=false
• 关键词: GOALI; Mechanically; Biased; Self; Assembly

The research objective of this GOALI project is to explore the use of a nano mechanical indenter as a stamping tool to direct the self-assembly of molecular beam epitaxy (MBE) grown quantum dots for the nano-manufacturability of novel 2-D and 3-D quantum structures. The proposed approach seeks to understand and control surface effects, such as isotropic and anisotropic strain fields, for the directed self-assembly of nanostructures. A nanoindenter will be used to investigate the ability to mechanically stamp precise nanopatterns of surface strain on which quantum dot nucleation, positioning, and functionality will be studied. The research program will support and enhance the educational activities at both the undergraduate and graduate level on the Virginia Commonwealth University and University of Arkansas campuses. Planned outreach to local high school students and teachers through on-going lectures and demonstrations will allow for immersion to the world of nanoscience and technology, and aims to promote early interest of underrepresented students into science and engineering.The impact of the proposed research will allow for the advancement of the science and technology of emerging quantum dot-based devices, as well as enhance existing technologies by providing a means for integrating novel nanodevices with existing semiconductor devices to create multifunctional nano-integrated micro systems. The transition of nanoindentation as a science and the instrument platform from an analytical instrument to a nano-manufacturing tool would be a vital breakthrough in the nanomechanical instrumentation industry. Furthermore, the use of a nanoindenter as a stamping tool should be applicable to patterning not only epitaxially self-assembled quantum dots but also chemically synthesized quantum dots, self-assembled quantum wires, as well as biological nanostructure patterning. Opening up the possibility for the fabrication of novel nanostructure architectures for electronic, optoelectronic and biological devices, molecular sensors, and interconnections.

这个GOALI项目的研究目标是探索使用纳米机械压头作为冲压工具来指导分子束外延（MBE）生长的量子点的自组装，以实现新型2-D和3-D量子结构的纳米可制造性。所提出的方法旨在了解和控制表面效应，如各向同性和各向异性的应变场，定向自组装的纳米结构。纳米压痕仪将被用来调查的能力，机械冲压精确的纳米粒子的表面应变，量子点成核，定位和功能将被研究。该研究项目将支持和加强弗吉尼亚联邦大学和阿肯色州大学校园的本科生和研究生教育活动。计划通过持续的讲座和演示向当地高中学生和教师推广，使他们沉浸在纳米科学和技术的世界中，旨在促进未被充分代表的学生对科学和工程的早期兴趣。拟议研究的影响将使新兴量子点设备的科学和技术进步，以及通过提供用于将新颖纳米器件与现有半导体器件集成以创建多功能纳米集成微系统的手段来增强现有技术。纳米压痕作为一门科学和从分析仪器到纳米制造工具的仪器平台的过渡将是纳米机械仪器行业的一个重要突破。此外，使用纳米压头作为冲压工具应适用于图案化不仅外延自组装量子点，而且化学合成的量子点，自组装量子线，以及生物纳米结构图案化。为电子、光电子和生物器件、分子传感器和互连的新型纳米结构结构的制造开辟了可能性。