COMPREHENSIVE INVESTIGATION OF SELECTED METAL OXIDES WITH APPLICATION FOR CLEAN ENERGY

对选定的金属氧化物及其在清洁能源中的应用进行全面研究

• 批准号: RGPIN-2014-04274
• 负责人: Szpunar, Barbara
• 金额: $ 1.38万
• 依托单位: University of Saskatchewan
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=633165
• 关键词: COMPREHENSIVE; INVESTIGATION; SELECTED; METAL; OXIDES

This proposal concerns the application of multi-scale modeling at both nuclear and atomistic levels. This work is unique because it combines nuclear simulations with materials modeling. Although the techniques to be used are well established, they have never been coupled together as proposed here. This work will apply state of the art, first principles (predictive) and improved modeling to investigate structural, optical, mechanical, and thermo-physical properties of novel and nuclear materials. The overall objective of this research is to develop a fundamental understanding of the properties of novel and nuclear materials. The short-term objectives over the next three years focus on (1) use of combined simulation of the radiation sources and atomistic molecular dynamics modeling of nuclear materials to achieve a better, fundamental understanding of the effects of radiation; (2) use of ab initio, predictive, and semiempirical methods to study the effect of radiation induced defects on the properties of materials on a large scale; (3) determining structural, mechanical, and thermo-physical properties for various nuclear fuels from simulations; (4) investigating optical and electronic properties of actinide oxides (with emphasis on U3O8); and (5) preparing interactive code for a reactor safety course.The semiconductive properties of uranium oxides are of interest since these oxides have dielectric constants much higher (e ~ 20) than SiO2 (3.5). Depleted uranium oxides can be recovered from nuclear waste and have potential application in solar cells and electronics. They are also a by-product of the production of enriched uranium. U3O8 is the most stable uranium oxide but there are no experimental data available about optical band gap. We have the required expertise to investigate the electronic structure and the band gap of U3O8, both experimentally (at Canadian Light Source) and theoretically. Cameco Inc. in Saskatoon can provide us with samples of depleted U3O8 that can be safely examined. Once the band gap has been determined both the optical and mechanical properties will be accurately determined from first principles calculations. They will be used to evaluate the potential application of U3O8 in solar panels. It will lay the groundwork for new applications for uranium oxides in the province of Saskatchewan beyond the current export of uranium ore. Accurate data on the mechanical and structural properties of U3O8 would allow the prediction of stresses when urania volume increases due to oxidation during an accident in a reactor or waste storage compartment.We have studied various nuclear fuels theoretically, especially inherently safe thoria with high thermal conductivity that prevents fuel melting by more efficient heat dissipation. However the experimental data for thermal conductivity of fuel show big differences and implications of burn-up-induced degradation is not well known. Monte Carlo code will be used to simulate the atoms displacements in fuels in operating fuel rods and a physical burnup will be evaluated. The parameters in classical molecular dynamics code will be tuned up using the first principles calculations and it will be used to evaluate the degradation of the thermal conductivity by the physical burnup. The comparison between urania and thoria fuel behaviours will be investigated.The developed thermal conductivity correlations for pure fuel and with inclusion of defects will be used in the new interactive software for multidisciplinary investigation of nuclear reactor safety and investigation of fuel melting in an accident similar to Fukushima. It is critical for the design of safer reactors to have access to new methods of simulating the properties of uranium oxides and new safer fuels (thoria, UC).

该建议涉及在核和原子水平上的多尺度建模的应用。这项工作是独一无二的，因为它结合了核模拟与材料建模。虽然所使用的技术已经很成熟，但从未像这里所建议的那样将它们结合在一起。这项工作将应用最先进的，第一原理（预测）和改进的建模来研究新型核材料的结构，光学，机械和热物理特性。这项研究的总体目标是对新材料和核材料的性质有一个基本的了解。未来三年的短期目标集中在：（1）使用辐射源的综合模拟和核材料的原子分子动力学模拟，以更好地从根本上了解辐射效应;（2）使用从头算、预测和半经验方法，以大规模研究辐射诱导缺陷对材料性能的影响;（3）通过模拟确定各种核燃料的结构、机械和热物理性质;（4）研究锕系氧化物的光学和电子性质（重点是八氧化三铀）;铀氧化物的介电常数（e ~ 20）很高，因此铀氧化物的介电性质是人们感兴趣的问题SiO2（3.5）。贫铀氧化物可以从核废料中回收，并在太阳能电池和电子产品中有潜在的应用。它们也是生产浓缩铀的副产品。U_3O_8是最稳定的铀氧化物，但没有关于光学带隙的实验数据。我们有必要的专业知识来研究U3 O 8的电子结构和带隙，无论是实验（在加拿大光源）还是理论。卡梅科公司在萨斯卡通能为我们提供可以安全检测的贫化八氧化三铀样本。一旦确定了带隙，光学和机械性能将根据第一原理计算准确地确定。它们将用于评估U3 O 8在太阳能电池板中的潜在应用。它将为萨斯喀彻温省铀氧化物的新应用奠定基础，超越目前的铀矿出口。准确的数据的U3 O 8的机械和结构特性将允许应力的预测时，氧化铀体积增加，由于在事故中的反应堆或废物存储隔间。我们已经研究了各种核燃料理论上，特别是固有的安全氧化钍具有高导热性，防止燃料熔化更有效的散热。然而，燃料的热导率的实验数据显示出很大的差异和燃耗引起的退化的影响是不为人所知的。用蒙特卡罗程序模拟了运行中的燃料棒中原子的位移，并计算了物理燃耗。经典分子动力学程序中的参数将使用第一性原理计算进行调整，并将用于评估物理燃耗对热导率的退化。将研究氧化铀和氧化钍燃料行为之间的比较，开发的纯燃料和含缺陷燃料的热导率相关性将用于新的交互式软件，用于核反应堆安全的多学科研究和类似福岛事故中燃料熔化的研究。设计更安全的反应堆，关键是要有新的方法来模拟铀氧化物和新的更安全的燃料（氧化钍，UC）的性质。