Submicron Remote Imaging using Specialty Fiber Coupled Hyperlens

使用特种光纤耦合超透镜进行亚微米远程成像

• 批准号: 1231852
• 负责人: Natalia Litchinitser
• 金额: $ 37万
• 依托单位: SUNY at Buffalo
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-08-01 至 2016-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1231852&HistoricalAwards=false
• 关键词: Submicron; Remote; Imaging; using; Specialty

The objective of this research is to develop a fiber-based endoscopic device with a metamaterial hyperlens at the end of the fiber, providing submicron resolution imaging for in-vivo diagnostics. The approach includes 1) theoretical design and experimental demonstration of a fiber-based hyperlens, 2) demonstration of transmission of high resolution images through a single fiber with an optimized design, and 3) identification of low-loss plasmonic materials for hyperlens fabrication to address the fundamental issue of losses that hinders the performance of optical metamaterials.Intellectual merit: Remote in-vivo endoscopic optical imaging plays a key role in the area of minimally invasive medicine. It is particularly critical for advancing the field of gastroenterology and oncology. The proposed research is transformative in nature as it will 1) advance fundamental knowledge of sub-wavelength imaging using metamaterial fiber-based structures, 2) address the critical need for a high resolution endoscopic imaging device by combining unique properties of metamaterials and specialty fibers, and 3) identify novel low-loss plasmonic materials for practical metamaterial devices.Broader impacts: The ability to rapidly and noninvasively image biological substances and tisssues with sub-wavelength resolution without biopsy, sectioning, or staining would be an extremely useful tool that would revolutionize many fields from clinical diagnostics to pharmaceutical manufacturing. The proposed system could lend itself to single molecule spectroscopy and enable new approaches to multimodal remote sensing. The proposed education and outreach program will contribute to the preparation and training of graduate and undergraduate students, including underrepresented minorities and women, K-12 students and high school teachers.

本研究的目的是开发一种基于光纤的内窥镜设备，在光纤末端具有超材料超透镜，为体内诊断提供亚微米分辨率成像。该方法包括1）基于光纤的超透镜的理论设计和实验演示，2）通过优化设计的单根光纤传输高分辨率图像的演示，3）识别用于超透镜制造的低损耗等离子体材料，以解决阻碍光学超材料性能的基本问题。远程在体内窥镜光学成像在微创医学领域起着关键作用。它对于推进胃肠病学和肿瘤学领域的发展尤为重要。这项研究具有变革性，因为它将1）推进使用超材料纤维结构的亚波长成像的基础知识，2）通过结合超材料和特种纤维的独特性能，满足对高分辨率内窥镜成像设备的迫切需求，3）为实用的超材料设备确定新型低损耗等离子体材料。在没有活检、切片或染色的情况下以亚波长分辨率对生物物质和组织进行快速和非侵入性成像的能力将是一种非常有用的工具，这将彻底改变从临床诊断到制药制造的许多领域。拟议的系统可以适用于单分子光谱学，并使新的方法，多模式遥感。拟议的教育和外联方案将有助于研究生和本科生的准备和培训，包括代表性不足的少数民族和妇女、K-12学生和高中教师。