Photonic nanowires for optical sensing and signal processing

用于光学传感和信号处理的光子纳米线

• 批准号: 239037-2011
• 负责人: Aitchison, Stewart
• 金额: $ 4.37万
• 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: 2012
• 资助国家: 加拿大
• 起止时间: 2012-01-01 至 2013-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=514421
• 关键词: Photonic; nanowires; optical; sensing; signal

Developments in nanotechnology underpin many areas of science and technology. The ability of accurately structure surfaces, materials and devices on the length scale of 1 - 100 nm opens up new device and system possibilities in the areas of ICT, biomedical sensing and environmental monitoring. The program of research outlined in this proposal covers the use of nanofabrication processes based around electron beam lithography and their application to develop high refractive index contrast waveguide structures. There are three areas where student projects will be focused over the next five years, a) electron beam lithography and process development b) photonic wires for wavelength conversion and 3) Photonic wires for optical sensing applications. In 2009 we officially opened our new electron beam lithography system, which allows features down to 10 nm to be defined across large areas. The high beam current, and low stitching errors possible with this tool allow a wide range of structures to be patterned, including nano-structured surfaces for biology, sensing and photonics. The quality of the underlying fabrication processes dictates the quality of the final waveguides, resonators and photonic crystals. We plan to optimize the ebeam patterning process to reduce the minimum feature size, improve writing time and reduce edge roughness that leads to high scattering losses in photonic waveguide structures. The use of high refractive index contrast waveguides to implement wavelength conversion has many advantages. The small core size increases the local intensity, the waveguide structure can be used to dispersion engineering the waveguide to enable phase matching and resonators can be used to further enhance the conversion efficiency. The ability to engineer the dispersion and field profile in a nanowire waveguide also has applications in optical sensing. By narrowing the waveguide, incorporating a photonic crystal, or defect state it is possible to control the overlap of the optical field with the sensing material. The program of research outlined in this application will provide an ideal training ground for students who will gain skills in nanofabrication, integrated optical circuit design and optical testing.

纳米技术的发展支撑着许多科学和技术领域。在1 - 100 nm的长度尺度上精确结构化表面、材料和器件的能力为ICT、生物医学传感和环境监测领域开辟了新的器件和系统可能性。在这项建议中概述的研究计划涵盖了使用基于电子束光刻及其应用的纳米纤维工艺，以开发高折射率对比度波导结构。在未来五年中，学生项目将集中在三个领域，a）电子束光刻和工艺开发B）用于波长转换的光子线和3）用于光学传感应用的光子线。2009年，我们正式启用了新的电子束光刻系统，该系统允许在大面积上定义低至10 nm的特征。高束流和低拼接误差允许使用该工具对各种结构进行图案化，包括用于生物学、传感和光子学的纳米结构表面。 底层制造工艺的质量决定了最终波导、谐振器和光子晶体的质量。我们计划优化电子束图案化过程，以减少最小特征尺寸，提高写入时间，并减少导致光子波导结构中高散射损耗的边缘粗糙度。 使用高折射率对比度波导实现波长转换具有许多优点。小的芯尺寸增加了局部强度，波导结构可以用于对波导进行色散工程以实现相位匹配，并且谐振器可以用于进一步提高转换效率。设计纳米线波导中的色散和场分布的能力也可应用于光学传感。通过使波导变窄、并入光子晶体或缺陷状态，可以控制光场与感测材料的重叠。本申请中概述的研究计划将为获得纳米制造、集成光路设计和光学测试技能的学生提供理想的培训场所。