Small lasers: Towards future photonic technologies

小型激光器：迈向未来的光子技术

• 批准号: RGPIN-2019-04726
• 负责人: Zhao, Songrui
• 金额: $ 2.77万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2021
• 资助国家: 加拿大
• 起止时间: 2021-01-01 至 2022-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=737816
• 关键词: Small; lasers; Towards; future; photonic

The global energy demand is projected to increase by almost 50% from 2012 to 2040. It is critical to address this challenge with new energy efficient technologies. The PI's research exploits high quality, low-dimensional materials to develop next generation devices. The proposed research continues the PI's endeavor in improving the efficiency of using energy through innovating photonic devices with group-III nitride nanostructures, far beyond the current state of the art. This program represents an ideal blend of dissemination of scientific knowledge across multiple disciplines and training of a new generation of high caliber scientists, and is unlike any other in Canada. It offers to train at least 4 students (2 PhD and 2 MEng) over the 5 year period. The long-term goal is to realize compact (size of a few cm3) and high power (watt-level) nanolasers in the visible and deep ultraviolet optical bands. To reach this long-term goal, it is imperative to understand the basic limitations of having such high power lasers, e.g., what are the key factors and what would be the optimized conditions. Therefore, in the short term, the PI's team aim to establish a fundamental understanding of these basic limitations, through developing color tunable and deep ultraviolet photonic crystal lasers with group-III nitride nanostructures, built upon the PI's preliminary results and intensive experience with these materials. Achieving these two short-term goals, the PI's team will establish strategies and building blocks to enable future high power compact nanolasers. Why is this research important? It is simply because we all need light and lasers are the most energy efficient technology to produce light; and the focused optical bands are highly relevant to our daily lives. In the visible, they will enable light sources that can be used for laser lighting, Li-Fi, among others; and with Li-Fi alone the projected market size is over $70B US dollars by 2023. In the deep ultraviolet, they will enable disruptive technologies, e.g., portable disinfection and bio/chemical sensing devices. This program will impact Canadians profoundly. Canada has vast north territories, where there are remote communities and deployed workers working there. In these areas, energy efficiency and device portability are critically important, as traditional energy sources, e.g., power grids, are hard to implement. The high power compact nanolaser technologies expected to be created through this program will positively impact their life quality, from lighting to drinking water disinfection, bio/chemical hazards detection, and so on. This program could also influence international communities. Recently, a student who wants to join the PI's research mentioned in email that the research is very attractive, because the potential technologies can help people in the student's home country. Clearly, the impact of this program on human society will surpass its impact on science and technology.

预计从 2012 年到 2040 年，全球能源需求将增加近 50%。PI 的研究利用高质量、低维材料来开发下一代设备，以应对这一挑战至关重要。 PI 继续致力于通过创新具有 III 族氮化物纳米结构的光子器件来提高能源使用效率，这远远超出了当前的技术水平。该计划代表了科学传播的理想结合。与加拿大其他任何学校不同，它提供跨学科知识和培训新一代高素质科学家，其长期目标是在 5 年内培训至少 4 名学生（2 名博士和 2 名硕士）。实现可见光和深紫外光波段的紧凑型（尺寸为几立方厘米）和高功率（瓦特级）纳米激光器要实现这一长期目标，必须了解拥有此类高功率激光器的基本局限性。 ,例如，关键因素是什么以及优化条件是什么，因此，在短期内，PI团队的目标是通过开发III族颜色可调谐和深紫外光子晶体激光器，对这些基本限制有一个基本的了解。基于 PI 的初步结果和在这些材料方面的丰富经验，PI 的团队将制定战略和构建模块，以实现未来的高功率紧凑型纳米激光器。为什么这项研究很重要？因为我们都需要光，而激光是产生光的最能源技术；而聚焦光波段与我们的日常生活高度相关，它们将实现高效光源。可用于激光照明、Li-Fi 等；仅 Li-Fi 预计到 2023 年市场规模将超过 70B 美元。在深紫外领域，它们将实现颠覆性技术，例如便携式消毒和生物/化学传感装置。该计划将对加拿大人产生深远的影响。加拿大拥有广阔的北部地区，那里有偏远社区和在那里工作的工人，在这些地区，能源效率和设备便携性至关重要，因为传统能源（例如电网）很难实施。预计通过该项目创建的高功率紧凑型纳米激光技术将积极影响他们的生活质量，从照明到饮用水消毒、生物/化学危害检测等。最近，一名学生也可能影响国际社会。想要加入PI的研究在电子邮件中提到，这项研究非常有吸引力，因为潜在的技术可以帮助学生祖国的人们，显然，这个项目对人类社会的影响将超过其对科学技术的影响。