Inner shell excitation spectroscopy and microscopy

内壳激发光谱和显微镜

• 批准号: 460-2010
• 负责人: Hitchcock, Adam
• 金额: $ 6.56万
• 依托单位: McMaster University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2014
• 资助国家: 加拿大
• 起止时间: 2014-01-01 至 2015-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=543874
• 关键词: Inner; shell; excitation; spectroscopy; microscopy

My group develops and uses electron impact and X-ray based inner-shell excitation spectroscopic instrumentation and techniques for materials analysis. Gas phase electron impact studies at McMaster are combined with synchrotron radiation based materials analysis at spectroscopy and microscopy beamlines at the Canadian Light Source (CLS, Saskatoon) and the Advanced Light Source (ALS, Berkeley). Our forte is linking basic spectroscopic understanding, developed by fundamental experimental and computational studies of pure gaseous and solid materials, to materials analysis applications using novel instrumentation and methods, particularly soft X-ray microscopies. A major component of this program is the development of new instrumentation and new techniques. In the next 5 years we will: (1) expand the instrumentation and applications of X-ray spectromicroscopy, focusing in particular on areas exploiting the unique capabilities of the CLS spectromicroscopy beamline. These include mapping orientation of polymer and nanofibres, magnetism in biology, and wide energy range, multi-element studies. Work will also continue at the ALS, focusing on helping develop a next generation scanning transmission X-ray microscope, with sub-10 nm spatial resolution and 3d chemical imaging of frozen biological and environmental samples. Other advanced microscopies at McMaster - ultra-resolution electron microscopies (TEM, SEM), Raman and atomic force microscopy - are used also. (2) perform gas phase dipole and non-dipole electron scattering studies, as well as continue the exciting program in quasi-elastic electron scattering. This area uses home-built instrumentation that is unique. The dipole studies provide the spectroscopic foundation for our X-ray microscopy analytical work while the non-dipole instrument allows us to probe fine details of electron scattering interactions and aspects of the electronic structure of molecules that cannot be easily studied using optical methods. The electron spectrometers are excellent lab-based tools for student training in instrumentation and science.

我的团队开发和使用基于电子撞击和X射线的内壳层激发光谱仪器和材料分析技术。麦克马斯特的气相电子撞击研究与加拿大光源(CLS，萨斯卡通)和高级光源(ALS，伯克利)的光谱和显微光束线上基于同步辐射的材料分析相结合。我们的强项是将通过对纯气体和固体材料的基础实验和计算研究而发展起来的基本光谱理解与使用新仪器和方法的材料分析应用相结合，特别是软X射线显微镜。该计划的一个主要组成部分是新仪器和新技术的开发。在接下来的5年里，我们将：(1)扩大X射线光谱显微镜的仪器和应用，特别是重点开发CLS光谱显微镜光束线的独特能力的领域。这些包括绘制聚合物和纳米纤维的方向图，生物学中的磁性，以及广泛的能量范围，多元素研究。ALS的工作还将继续，重点是帮助开发下一代扫描透射式X射线显微镜，具有低于10纳米的空间分辨率和冻结生物和环境样品的3D化学成像。麦克马斯特的其他先进显微镜--超分辨电子显微镜(透射电子显微镜、扫描电子显微镜)、拉曼显微镜和原子力显微镜--也被使用。(2)进行气相偶极和非偶极电子散射研究，并继续准弹性电子散射的激发程序。这一地区使用的是独一无二的自制仪器。偶极子研究为我们的X射线显微镜分析工作提供了光谱基础，而非偶极子仪器使我们能够探测电子散射相互作用的精细细节，以及使用光学方法无法轻松研究的分子电子结构方面。电子能谱仪是学生在仪器和科学方面进行培训的极好的实验室工具。