介电特性的表征及其对 MAS-DNP NMR 应用的影响

IF 2 3区 化学 Q3 BIOCHEMICAL RESEARCH METHODS Journal of magnetic resonance Pub Date : 2024-08-01 DOI:10.1016/j.jmr.2024.107742
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引用次数: 0

摘要

材料的介电性质对魔角旋转-动态核极化(MAS-DNP)核磁共振实验中使用的微波束的传播和吸收起着至关重要的作用。尽管在样品制备方面不断进行优化,但常规 MAS-DNP NMR 应用往往达不到理论灵敏度极限。我们提供了一个不同的视角,报告了用于 MAS-DNP NMR 实验的各种材料的折射率和消光系数,频率范围从 70 GHz 到 960 GHz。了解了这些材料的介电特性,就能准确模拟电子入射频率,从而指导设计更高效的硬件以及生物或材料样品的制备。实验说明了在 395 GHz/1H 600 MHz 频率下用于 DNP 的四种不同转子材料(蓝宝石、钇稳定氧化锆(YSZ)、氮化铝(AlN)和 SiAlON 陶瓷)。最后,电磁模拟和最先进的 MAS-DNP 数值模拟合理地解释了使用亚硝基双烷基时观察到的磁场增强依赖性,为改进高磁场下的 MAS-DNP NMR 提供了启示。
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Characterization of dielectric properties and their impact on MAS-DNP NMR applications

The dielectric properties of materials play a crucial role in the propagation and absorption of microwave beams employed in Magic Angle Spinning − Dynamic Nuclear Polarization (MAS-DNP) NMR experiments. Despite ongoing optimization efforts in sample preparation, routine MAS-DNP NMR applications often fall short of theoretical sensitivity limits. Offering a different perspective, we report the refractive indices and extinction coefficients of diverse materials used in MAS-DNP NMR experiments, spanning a frequency range from 70 to 960 GHz. Knowledge of their dielectric properties enables the accurate simulation of electron nutation frequencies, thereby guiding the design of more efficient hardware and sample preparation of biological or material samples. This is illustrated experimentally for four different rotor materials (sapphire, yttria-stabilized zirconia (YSZ), aluminum nitride (AlN), and SiAlON ceramics) used for DNP at 395 GHz/1H 600 MHz. Finally, electromagnetic simulations and state-of-the-art MAS-DNP numerical simulations provide a rational explanation for the observed magnetic field dependence of the enhancement when using nitroxide biradicals, offering insights that will improve MAS-DNP NMR at high magnetic fields.

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来源期刊
CiteScore
3.80
自引率
13.60%
发文量
150
审稿时长
69 days
期刊介绍: The Journal of Magnetic Resonance presents original technical and scientific papers in all aspects of magnetic resonance, including nuclear magnetic resonance spectroscopy (NMR) of solids and liquids, electron spin/paramagnetic resonance (EPR), in vivo magnetic resonance imaging (MRI) and spectroscopy (MRS), nuclear quadrupole resonance (NQR) and magnetic resonance phenomena at nearly zero fields or in combination with optics. The Journal''s main aims include deepening the physical principles underlying all these spectroscopies, publishing significant theoretical and experimental results leading to spectral and spatial progress in these areas, and opening new MR-based applications in chemistry, biology and medicine. The Journal also seeks descriptions of novel apparatuses, new experimental protocols, and new procedures of data analysis and interpretation - including computational and quantum-mechanical methods - capable of advancing MR spectroscopy and imaging.
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