Extreme Photon Science and Technology with a Twist

扭曲的极限光子科学与技术

• 批准号: RGPIN-2019-06811
• 负责人: Ozaki, Tsuneyuki
• 金额: $ 3.64万
• 依托单位: Institut national de la recherche scientifique
• 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=739120
• 关键词: Extreme; Photon; Science; Technology; Twist

Ultrafast laser science has had, and continues to have enormous impact in multiple areas of science and technology. This has clearly been reconfirmed by the recent Nobel Prize in Physics awarded to Prof. Donna Strickland and Prof. Gérard Mourou, "for their method of generating high-intensity, ultra-short optical pulses". The frontiers of ultrafast laser science have continued to expand over the past 30 years, and with it opening new areas of application, which started from basic physics and chemistry, and is now extending to many sectors of importance to Canada, such as energy, pharmaceutics and medicine. My past Discovery Grants have supported a research programme on Extreme Photon Science & Technology (EPST): the science of ultrafast photon sources with extreme characteristics (such as in terms of wavelength, peak intensity and pulse duration), and developing innovative technologies for various applications that take advantage of such unique photon sources. Research in EPST has significantly advanced over the years, especially in the X-ray range (high-order harmonic generation, HHG) and in the far-infrared (terahertz [THz] frequencies). Looking back, it turns out that my approaches to advance EPST have been rather atypical and unconventional, which at first sight might seem to contradict or counter common understandings. In many such cases, such Maverick approaches (with a twist) has led to unexpected outcomes, and in some cases opening up surprising and new opportunities, thus pushing forward the frontiers of EPST. The long-term goal of my research is to pioneer and advance Extreme Photon Science & Technology (EPST), to unravel new knowledge and to apply the research outputs to find solutions to challenges currently faced in various sectors of importance to Canada. To achieve this goal, I propose to further deepen our understandings of the findings obtained from the atypical approaches of my past Discovery grants, as well as to design and study new techniques in EPST with a twist. To this end, the mid-term objectives of the proposed Discovery Grant is (i) to study the interaction of intense THz radiation with various materials (such as DNA, semiconductors and graphene) at unprecedented THz fields and repetition rates, and elucidate their mechanisms; (ii) to study the ultrafast dynamics of autoionizing states via high-order harmonic spectroscopy using HHG from laser ablation plume of various materials; (iii) to develop novel techniques to improve and modify a unique equipment, the THz Chemical Microscope, and apply them for studies in various sectors, such as cancer research, tick-borne disease detection and the treatment of algal toxins. Outcomes of this Discovery programme should not only advance our knowledge, but may also result in innovative methods to detect and monitor metastatic cancer, diagnose Lyme disease, and provide novel methods to control toxins produced by bacteria, which may pollute our water source.

超快激光科学已经并将继续在多个科学技术领域产生巨大影响。最近授予Donna Strickland教授和Gérard Mourou教授的诺贝尔物理学奖清楚地再次证实了这一点，他们“以表彰他们产生高强度、超短光脉冲的方法”。在过去的30年里，超快激光科学的前沿不断扩大，随之而来的是新的应用领域，从基础物理和化学开始，现在扩展到对加拿大重要的许多部门，如能源、制药和医药。我过去的发现拨款支持了一项极端光子科学与技术(EPST)的研究计划：研究具有极端特征(如波长、峰值强度和脉冲持续时间)的超快光子源，并为利用这种独特光子源的各种应用开发创新技术。EPST的研究多年来取得了显著进展，特别是在X射线范围(高次谐波产生，HHG)和远红外(太赫兹[THz]频率)方面。回过头来看，我推进EPST的方法相当非典型和非常规，乍一看似乎与普遍理解相矛盾或背道而驰。在许多这样的情况下，这种小牛队的方法(有一点转折)导致了意想不到的结果，在某些情况下还带来了令人惊讶的新机会，从而推动了EPST的前沿。我研究的长期目标是开拓和推进极端光子科学与技术(EPST)，揭示新知识，并应用研究成果找到解决方案，以应对目前对加拿大至关重要的各个领域面临的挑战。为了实现这一目标，我建议进一步加深我们对从我过去的探索基金的非典型方法中获得的结果的理解，以及在EPST中设计和研究新的技术。为此，拟议的发现拨款的中期目标是：(I)研究在前所未有的太赫兹场和重复频率下，强烈的太赫兹辐射与各种材料(如DNA、半导体和石墨烯)的相互作用，并阐明其机制；(Ii)利用来自各种材料的激光烧蚀羽流中的高次谐波，利用高次谐波光谱研究自电离状态的超快动力学；(Iii)开发新技术，以改进和改造独特的设备--太赫兹化学显微镜，并将其应用于不同部门的研究，如癌症研究、壁虱传播的疾病检测和藻类毒素的治疗。这一发现计划的成果不仅应该促进我们的知识，还可能导致发现和监测转移癌症的创新方法，诊断莱姆病，并提供新的方法来控制细菌产生的毒素，这些毒素可能污染我们的水源。