Controlling nano to microscale dynamics with light: from fundamental research to advanced fabrication

用光控制纳米到微米级动力学：从基础研究到先进制造

• 批准号: 298146-2013
• 负责人: Fraser, James
• 金额: $ 3.79万
• 依托单位: Queen's University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=633245
• 关键词: Controlling; nano; microscale; dynamics; light

We must transform to a more sustainable society. Advanced materials and new manufacturing methods will play a central role in the effort to develop renewable energy sources and reduced-impact high tech fabrication processes. We will use light as a probe and also as a scapel, to study, control and fabricate systems on the micro and nanoscale. Our research follows two main thrusts:A) Lasers are used to precision cut a wide range of consumer products, from cars to smartphones. Even with such success, to produce a product with a specific 3D shape, one must resort to more wasteful and less precise tools since a laser beam cannot be stopped in mid-flight. Due to NSERC DG funding, we were able to invent a novel technique to control laser penetration depth in arbitrary materials, ranging from steel to bone. We will apply this potentially transformative technology to improve high power laser welding and fabricate new artificial materials with submicron precision. Our results will reduce manufacturing time, helping the Canadian automotive, microelectronics and aerospace industries. More importantly, active depth control may open laser processing to completely new approaches or materials that are currently out of reach. B) In a typical solar cell, one photon from the sun excites one electron in the cell. Recently, theorists have predicted that we can double the electron conversion efficiency in one of the most environmentally alluring materials, carbon, in the form a nanotube. Though the potential of carbon nanotube solar cells is huge, the challenges are immense. We need to understand their basic fundamental properties for them to serve as a building block for a novel opto-electronic industry. An important component of this effort is to track the birth and motion of electrons in the tiny nm-diameter tubes with extreme high time resolution only possible with ultrafast optics.An essential component of this research is the contributions and training of students with sophisticated optical tools, novel materials, nano-characterization and advanced manufacturing.

我们必须转变为一个更可持续的社会。先进材料和新的制造方法将在开发可再生能源和减少影响的高科技制造工艺方面发挥核心作用。我们将使用光作为探针，也作为一个刻度，研究，控制和制造系统在微纳米尺度。我们的研究遵循两个主要方向：A)激光用于精确切割各种消费产品，从汽车到智能手机。即使取得了这样的成功，要生产出具有特定3D形状的产品，也必须求助于更浪费、更不精确的工具，因为激光束无法在飞行中途停止。由于NSERC DG的资助，我们能够发明一种新技术来控制激光在任意材料中的穿透深度，从钢到骨头。我们将应用这种潜在的变革性技术来改进高功率激光焊接，并以亚微米精度制造新的人工材料。我们的研究结果将缩短制造时间，帮助加拿大的汽车、微电子和航空航天工业。更重要的是，主动深度控制可以打开激光加工的全新方法或材料，目前无法达到。B)在典型的太阳能电池中，来自太阳的一个光子激发电池中的一个电子。最近，理论学家预测，我们可以将碳纳米管这种最环保的材料之一的电子转换效率提高一倍。虽然碳纳米管太阳能电池的潜力是巨大的，但挑战也是巨大的。我们需要了解它们的基本特性，以便它们成为新型光电工业的基石。这项工作的一个重要组成部分是跟踪电子在微小的纳米直径管中的诞生和运动，只有使用超快光学才能实现极高的时间分辨率。这项研究的一个重要组成部分是学生在精密光学工具、新材料、纳米表征和先进制造方面的贡献和培训。