DNP enhanced solid state NMR of green and sustainable materials

绿色可持续材料的 DNP 增强固态核磁共振

• 批准号: 2115050
• 金额: --
• 依托单位: University of Nottingham
• 依托单位国家: 英国
• 项目类别: Studentship
• 财政年份: 2018
• 资助国家: 英国
• 起止时间: 2018 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=studentship-2115050
• 关键词: DNP; enhanced; solid; state; NMR

Project background (identification of the problem and its importance and relevance to sustainability)For the development of green and sustainable materials, greater understanding of structure-property relationships will help to streamline their design and synthesis allowing for more efficient processes. To gain this deep understanding, advanced analytical techniques are required.Solid-state NMR is a powerful technique for studying the molecular-level detail of complex and heterogeneous materials. However, even with the high magnetic fields available today, solid-state NMR suffers from low sensitivity, because of the small nuclear spin polarizations involved, so that long acquisitions or large samples are required. Fortunately, weak NMR signals can be enhanced at low temperatures (~100 K) by dynamic nuclear polarization (DNP) in which the large electron spin polarization from an implanted radical is transferred to nearby nuclei. Progress with high-power microwave sources (gyrotrons) has made DNP possible at the high fields found in modern NMR spectrometers. Large signal enhancements (up to 300-fold) have been achieved for frozen biomolecules, corresponding to a reduction by a factor of 100,000 in experiment time.More recently, DNP-enhanced NMR signals have been recorded for the functionalizing groups at the pore surfaces in meso-structured hybrid silica materials using radicals implanted from a solution impregnated into the pores. Despite the modest (20-fold) enhancement, structural details, such as the conformation of the functionalizing groups and their distribution were established from 13C and 29Si NMR spectra. This study triggered a revolution in materials NMR, making many new applications feasible for the first time.DNP has the potential to transform solid-state NMR into the technique of choice for the characterization of green and sustainable materials. Currently, most DNP studies of this type involve impregnating the sample with a solution of a specially designed biradical with polarization transfer to the nuclei of interest, followed by polarization transport through the solvent matrix. This process is a critical factor, with changes in solvent, radical concentration, sample morphology and surface area etc. requiring empirical optimization to maximize the enhancement. The sample preparation step represents a problem for DNP-enhanced solid-state NMR, since the resulting enhancement is not reproducible, and the impregnating solution may not be compatible with the material of interest.To improve the applicability of DNP-enhanced solid-state NMR this project will develop new sample preparation techniques. These new techniques will be used to analyse a variety of green and sustainable materials, chosen from research ongoing in the CDT, including polymers, metal organic framework materials and catalysts. The new sample preparation techniques proposed are:1) Supercritical carbon dioxide as an impregnation solvent. 2) Mesocellular foams as DNP matrices(details about each technique available on request)Areas: Analytical Science, Catalysis, Energy Storage, Functional Ceramics and Inorganics, Materials for Energy Applications, Polymer Materials and Surface Science

项目背景（确定问题及其对可持续性的重要性和相关性）对于绿色和可持续材料的开发，更好地理解结构-性能关系将有助于简化其设计和合成，从而实现更有效的工艺。为了获得这种深入的理解，需要先进的分析技术。固态核磁共振是一种强大的技术，用于研究复杂和非均匀材料的分子水平的细节。然而，即使在当今可用的高磁场下，固态NMR也遭受低灵敏度的困扰，因为所涉及的小的核自旋极化，使得需要长时间采集或大样本。幸运的是，弱的NMR信号可以在低温（~100 K）下通过动态核极化（DNP）增强，其中来自注入自由基的大电子自旋极化被转移到附近的核。高功率微波源（回旋管）的进步使DNP在现代NMR光谱仪中发现的高场成为可能。大的信号增强（高达300倍）已经实现了冷冻的生物分子，相应的减少了100，000倍的实验time.More最近，DNP增强的NMR信号已被记录为在介孔结构的杂化二氧化硅材料中的孔表面的官能化基团，使用从浸渍到孔中的溶液中注入的自由基。尽管适度（20倍）的增强，结构细节，如构象的官能化基团和它们的分布，建立从13 C和29 Si NMR光谱。这项研究引发了材料NMR的革命，使许多新的应用首次成为可能。DNP有潜力将固态NMR转变为表征绿色和可持续材料的首选技术。目前，这种类型的DNP研究大多涉及浸渍样品与一个专门设计的双自由基的溶液与极化转移到感兴趣的核，然后通过溶剂基质的极化传输。该过程是一个关键因素，溶剂、自由基浓度、样品形态和表面积等的变化需要经验优化以最大化增强。样品制备步骤代表了DNP增强固态NMR的一个问题，因为所产生的增强是不可再现的，并且浸渍溶液可能与感兴趣的材料不相容。为了提高DNP增强固态NMR的适用性，本项目将开发新的样品制备技术。这些新技术将用于分析从CDT正在进行的研究中选择的各种绿色和可持续材料，包括聚合物，金属有机框架材料和催化剂。提出的新的样品制备技术是：1）超临界二氧化碳作为浸渍溶剂。2)介孔泡沫作为DNP基质（可根据要求提供每种技术的详细信息）领域：分析科学，催化，储能，功能陶瓷和无机物，能源应用材料，聚合物材料和表面科学