Exploring solid state reaction pathways with IN SITU methods

用原位方法探索固态反应途径

• 批准号: 261568-2008
• 负责人: Bieringer, Mario
• 金额: $ 2.19万
• 依托单位: University of Manitoba
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2011
• 资助国家: 加拿大
• 起止时间: 2011-01-01 至 2012-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=479896
• 关键词: Exploring; solid; state; reaction; pathways

Our materials discovery program focuses on magnetic materials, ion conductors and photocatalysts. We emphasize the importance of solid state preparation methods for the discovery and modification of these materials. The in-depth investigations of solid state reaction pathways provides opportunities to alter extended structures, control oxidation states and trap metastable and intermediate structures. Systems of interest range from transition metal oxides, oxychlorides to sulfychlorides. These systems permit rationalizing magnetic and electronic properties in ceramics as a function of their structures. Materials' properties strongly depend on solid state structures, it is therefore crucial to reliably determine crystalline solid state structures. Powder X-ray and neutron diffraction are particularly powerful methods for the investigation of these phases. The recent progress in diffraction instrumentation and analysis software allows to follow solid state reactions in real-time. Using in-situ powder X-ray diffraction we are investigating solid state reaction pathways during phase formation, reduction and oxidation of transition metal oxides such as vanadates and vanadites with zircon, perovskite, bixbyite, defect fluorite and pyrochlore structures. In-situ experiments will improve our understanding and will aid the optimization of solid state synthesis methods. We also investigate rare-earth transition metal chalcogenidechlorides as model compounds for low-dimensional magnetism. In oxychlorides low-dimensional paramagnetic sublattices are formed by means of anisotropic magnetic exchange paths due to anion ordering. Systems under investigation encompass oxychlorides and sulfychlorides with ordered and disordered anion lattices as well as transition metal oxides representing single anion lattices. These model systems provide an opportunity to evaluate the impact of anion ordering on magnetic exchange interactions in extended solids. We also investigate crystallographic phase transitions in oxides. The research program combines a large synthetic component with the investigation of physical properties in order to identify structure-property relations in solids

我们的材料发现计划侧重于磁性材料，离子导体和光催化剂。我们强调了固态制备方法对这些材料的发现和改性的重要性。固态反应途径的深入研究提供了改变扩展结构、控制氧化态和捕获亚稳态和中间结构的机会。感兴趣的系统范围从过渡金属氧化物、氯氧化物到磺酰氯。这些系统允许合理化的磁性和电子性能在陶瓷作为其结构的功能。材料的性质在很大程度上取决于固态结构，因此可靠地确定晶体固态结构至关重要。粉末X射线和中子衍射是研究这些相的特别有效的方法。衍射仪器和分析软件的最新进展允许实时跟踪固态反应。利用原位粉末X射线衍射，我们正在研究过渡金属氧化物，如钒酸盐和钒酸盐与锆石，钙钛矿，方铁锰矿，缺陷萤石和烧绿石结构的相形成，还原和氧化过程中的固态反应途径。原位实验将提高我们的理解，并将有助于优化固相合成方法。我们还研究了稀土过渡金属硫族氯化物作为模型化合物的低维磁性。在氯氧化物中，由于阴离子有序化，通过各向异性磁交换路径形成低维顺磁亚晶格。研究的体系包括具有有序和无序阴离子晶格的氯氧化物和磺酰氯，以及代表单一阴离子晶格的过渡金属氧化物。这些模型系统提供了一个机会，以评估阴离子排序的磁交换相互作用在扩展固体的影响。我们还研究了氧化物的晶体相变。该研究计划结合了一个大的合成成分与物理性质的调查，以确定固体中的结构-性质关系