International Research Fellowship Program: Hyperpolarized Solid State NMR Spectra of Materials and Catalysis Using Dynamic Nuclear Polarization
Casabianca Leah B, Chicago IL
Investigators
Abstract
0965137 Casabianca The International Research Fellowship Program enables U.S. scientists and engineers to conduct nine to twenty-four months of research abroad. The program's awards provide opportunities for joint research, and the use of unique or complementary facilities, expertise and experimental conditions abroad. This award will support a twenty-four-month research fellowship by Dr. Leah B. Casabianca to work with Dr. Lucio Frydman at the Weizman Institute in Israel. Nuclear Magnetic Resonance (NMR) spectroscopy is undoubtedly one of the most versatile and useful tools for the determination of structure and dynamics in chemical systems and materials. No other technique compares in the wealth of atomistic detail that can become available from this kind of spectroscopy. The greatest disadvantage of NMR spectroscopy, however, is its low sensitivity. NMR would be ideally suited for structural studies of catalytic organic systems, functionalized surfaces, or inorganic nanotubes ? should only its sensitivity problems be surmounted. This goal of this work is the development of new NMR techniques exploiting cryogenic dynamic nuclear polarization (DNP) to characterize hyperpolarized nuclei in static solids. The application of DNP to metal nuclei in solids will be validated, optimized and understood through the development of pulse sequences, optimal hyperpolarization conditions for polarization transfer specifically to metal nuclei, and hardware for use in cryogenic environments. These approaches will then be used to examine metal nuclei in catalysts and inorganic nanotubes. A concomitant goal of this project is to examine the feasibility of using endogenous paramagnetic impurities present in single-walled carbon nanotubes (SWNTs) and nanodiamonds as polarizing agents for DNP, enhancing the signal of 13C nuclei in these carbon nanomaterials. Catalysts are ubiquitous in synthetic and industrial chemistry as well as in everyday life, inorganic nanotubes have unique potential applications due to their non-toxic nature, and carbon nanomaterials have applications ranging from membranes and sensors to batteries and nanoelectronics. Whereas structural characterization in these fields has traditionally been dominated by low-resolution techniques, sensitivity-enhanced NMR has the potential to allow atomic-level characterization of these and other emerging advanced materials. The proposed work will lead to advances in the field of hyperpolarized solid-state NMR, and will also have a positive impact on other fields including catalysis and materials science. The techniques being developed will allow the characterization of systems that have traditionally been difficult to study by NMR due to the inherent sensitivity limitations of this method, thus advancing the field of NMR by increasing the applicability of this technique. In addition, this project will contribute to the understanding of hyperpolarization processes in general. This work will benefit society through the potential applications of metal-containing catalysts, inorganic nanotubes, SWNTs, and other carbon-based nanomaterials. Atomic-level structural characterization of these materials will allow applications of these systems in the biomedical, electronics, automotive, and aerospace industries to be realized.
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