Advanced Instrumentation for Research in Accelerator Mass Spectrometry

用于加速器质谱研究的先进仪器

• 批准号: RGPIN-2016-04800
• 负责人: Kieser, William
• 金额: $ 1.97万
• 依托单位: University of Ottawa
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=709473
• 关键词: Advanced; Instrumentation; Research; Accelerator; Mass

Accelerator mass spectrometry (AMS) is a technology used to measure concentrations of rare atoms or isotopes in milligram samples with sensitivities as high as 1 part in 1015 (thousand million million). Such measurements are generally limited to elements which readily make negative ions (anions) and for which anions of other elements with the same mass (isobars) do not exist, e.g. 14C and 129I. If atomic isobars do exist, measurements require the use of larger accelerators (>5 MV) and tedious sample preparation chemistry. Two innovations begun at the IsoTrace Laboratory (Toronto), shortly before it was closed, provided the groundwork needed for the extension of AMS to a much larger fraction of the periodic table. These are: (i) the use of fluoride molecular anions to increase the production of the anions required for AMS and (ii) the use of radio-frequency quadrupole ion guides in cooling and reaction cells to eliminate both atomic and molecular isobars at very low energies - for which a prototype system, the Isobar Separator for Anion (ISA) has been developed and patented. The primary and long-term goal of this research is to more fully understand the physical (and some chemical) processes which make this equipment work, but which seem to limit its further development. This understanding will be tested by formulating new procedures and components, which, when successful, will become part of future AMS systems. The commissioning of the A. E. Lalonde AMS Laboratory at the University of Ottawa, and the incorporation of recently developed equipment from IsoTrace, provide a unique opportunity to deepen that understanding, to develop new techniques based on this knowledge and to explore the many new applications which they enable. The near-term research program will include: a) investigating new phenomena observed in earlier work on the ISA. These include the necessity to control the energy and position of the ions, the search for reaction gases with states to which electrons can be resonantly transferred and the determination of the structure of the analyte, isobar or reaction gas molecules. b) investigating processes in the formation of fluoride anions. New methods for generating larger molecular anion beams were recently discovered using the high current ion sources at the Lalonde Lab, but these processes are not yet understood. c) re-starting the gas ion source research, delayed by the IsoTrace closing. This is motivated by the need of many scientists to analyze compound-specific (hence smaller) 14C samples with the eventual extension of this capability to tritium and 129I measurements, and d) continuing collaboration with researchers using AMS to support their work in diverse fields such as tracing pollutant pathways, determining chronologies for geological processes, enabling nuclear forensic investigations, testing new pharmaceuticals and monitoring aspects of human health.

加速器质谱仪(AMS)是一种用于测量毫克样品中稀有原子或同位素浓度的技术，灵敏度高达1015(亿亿分之一)。这种测量一般限于容易产生负离子(阴离子)的元素，而不存在相同质量的其他元素的阴离子(同量异位素)，例如14C和129I。如果原子等压素确实存在，测量需要使用更大的加速器(&gt；5 mV)和繁琐的样品制备化学。IsoTrace实验室(多伦多)在关闭前不久开始了两项创新，为将AMS扩展到元素周期表的更大部分提供了所需的基础。它们是：(I)使用氟化物分子阴离子来增加AMS所需的阴离子的生产，以及(Ii)在冷却和反应池中使用射频四极离子导向器，以在非常低的能量下消除原子和分子等压素--为此开发了一个原型系统--Isobar Separator for Nion(ISA)，并获得了专利。 这项研究的主要和长期目标是更全面地了解使该设备工作的物理(和一些化学)过程，但这些过程似乎限制了它的进一步发展。这一理解将通过制定新的程序和组件来检验，一旦成功，这些程序和组件将成为未来AMS系统的一部分。渥太华大学A.E.Lalonde AMS实验室的投入使用，以及IsoTrace公司最近开发的设备的加入，为加深这种理解、开发基于这种知识的新技术和探索这些技术带来的许多新应用提供了一个独特的机会。近期的研究计划将包括： A)调查在早期关于ISA的工作中观察到的新现象。这些包括控制离子的能量和位置的必要性，寻找具有电子可以共振转移到的状态的反应气体，以及确定分析物、等压素或反应气体分子的结构。 B)研究氟离子的形成过程。最近，拉隆德实验室使用强流离子源发现了产生更大分子阴离子束的新方法，但这些过程尚不清楚。 C)重新启动气体离子源研究，因同位素示踪关闭而延迟。这是因为许多科学家需要分析化合物特有的(因此较小的)14C样品，并最终将这种能力扩展到氚和129I测量，以及 D)继续与使用AMS的研究人员合作，支持他们在不同领域的工作，如追踪污染物路径、确定地质过程的年代、支持核法医调查、测试新药物和监测人类健康的各个方面。