SuperSTEM Access for advanced electron microscopy studies of magnetic nanocomposite materials

SuperSTEM Access 用于磁性纳米复合材料的高级电子显微镜研究

基本信息

批准号：
EP/F03699X/1
负责人：
Gavin Mountjoy
金额：
$ 0.25万
依托单位：
University of Kent
依托单位国家：
英国
项目类别：
Research Grant
财政年份：
2008
资助国家：
英国
起止时间：
2008 至无数据
项目状态：
已结题

来源：
https://gtr.ukri.org/projects?ref=EP%2FF03699X%2F1
关键词：
SuperSTEM Access advanced electron microscopy

项目摘要

The synthesis and characterisation of nanomaterials is a very exciting emerging field of research which has received important scientific and technological attention. Nanomaterials can be found as bulk materials with grain size in the nanometer range or as separate nanoparticles. The large surface-to-volume ratio of nanoparticles means properties can differ significantly from those of the corresponding conventional materials. The magnetic properties show a dramatic dependence on particle size. As the particle size decrease, the formation of ferromagnetic domain walls becomes unfavourable, and superparamagnetism occurs. Arrays of nanoparticles can be arranged in two- and three-dimensional structures, whose electric, optical, transport and magnetic properties depend on the interaction between nanoparticles. Nanoparticles dispersed in a protective medium are called nanocomposites, and consist of two phases: the nanoparticles (dispersed phase), and the matrix (protective medium), which prevents direct contact. Such nanocomposites yield interesting magnetic, electric and catalytic properties depending on the ratio between the dispersed and matrix phases. For example, there will be a transition from magnetically isolated to interacting behaviour. One of the main challenges is characterising the morphology, surface and atomic structures of nanomaterials, which are keys to their technological properties. However, conventional techniques may be limited for nanomaterials due to the small particle size. For example, X-ray diffraction (XRD) spectra of nanocrystalline powders evolve to resemble an amorphous sample as particle size decreases. The complementary use of different structural characterisation techniques is needed. Furthermore, most standard techniques measure an average over the whole sample, and cannot distinguish between different nanoparticles, or different regions of a single nanoparticle. There is a great need to provide nm-scale analysis of the structural and compositional homogeneity of the nanoparticles, which can strongly affect their behaviour. For example, metallic particles in nanocomposite materials with oxide matrices often have a surface oxide layer which can reduce the effective ferromagnetic volume. To understand this phenomena requires identifying the surface oxide and its thickness. Ideally suited to this problem are advanced electron microscopy techniques which can probe nm-scale regions to reveal information on structure, via high resolution electron microscopy (STEM), or composition, via electron energy loss spectroscopy (EELS). The aim of this proposal is to apply the advanced electron microscopy techniques of STEM and EELS which are available to the SuperSTEM facility to study nanocomposites containing Fe/Co alloy and oxide nanoparticles.

纳米材料的综合和表征是一个非常令人兴奋的新兴研究领域，它引起了重要的科学和技术关注。可以在纳米材料中发现纳米材料，其粒度在纳米范围内或单独的纳米颗粒。纳米颗粒的较大表面体积比意味着性能与相应的常规材料的性质可能有显着差异。磁性特性显示出对粒径的巨大依赖性。随着粒径的减小，铁磁域壁的形成变得不利，并且会发生超paragnetism。纳米颗粒的阵列可以在两维结构中排列，其电，光学，传输和磁性特性取决于纳米颗粒之间的相互作用。分散在保护性培养基中的纳米颗粒称为纳米复合材料，由两个阶段组成：纳米颗粒（分散相）和基质（保护介质），可防止直接接触。这种纳米复合材料根据分散相和基质相之间的比率产生有趣的磁性，电和催化性能。例如，将有从磁性隔离到相互作用行为的过渡。主要挑战之一是表征纳米材料的形态，表面和原子结构，这些纳米材料是其技术特性的关键。但是，由于粒径较小，纳米材料的常规技术可能受到限制。例如，纳米晶体粉末的X射线衍射（XRD）光谱随着粒径降低而演变为类似于无定形样品。需要互补的不同结构表征技术。此外，大多数标准技术在整个样品中测量平均水平，无法区分不同的纳米颗粒或单个纳米颗粒的不同区域。非常需要对纳米颗粒的结构和组成均匀性进行NM规模分析，这可以强烈影响其行为。例如，具有氧化物基质的纳米复合材料中的金属颗粒通常具有表面氧化物层，可以减少有效的铁磁体积。要了解这种现象需要识别表面氧化物及其厚度。理想适合此问题的是高级电子显微镜技术，可以通过电子能量损失光谱（EELS）探测通过高分辨率电子显微镜（STEM）或组成来揭示结构的信息。该提案的目的是应用茎和鳗的先进电子显微镜技术，这些技术可供超级巨星设施使用，以研究含有Fe/Co合金和氧化物纳米颗粒的纳米复合材料。