High-magnetic-field nuclear magnetic resonance (NMR) has manifested itself as an indispensable tool in modern scientific research in the fields of physics, chemistry, materials science, biology, and medicine, among others, owing to its great advantages in both measurement sensitivity and quantum controllability. At present, the use of pulsed fields is the only controllable and nondestructive way to generate high magnetic fields of up to 100 T. NMR combined with pulsed fields is therefore considered to have immense potential for application in multiple scientific and technical disciplines. Irrespective of the paramount technical challenges, including short duration of the pulsed fields, unstable plateaus, and poor field homogeneity and reproducibility, great progress has been made in a number of pulsed-field laboratories in Germany, France, and Japan. In this paper, we briefly review the status of the pulsed-field NMR technique, as well as its applications in multiple disciplines. We also discuss future trends with regard to the upgrading of pulsed-field NMR.

中文翻译：

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脉冲场核磁共振：现状与前景

高磁场核磁共振（NMR）由于在测量灵敏度上均具有很大的优势，因此已成为物理，化学，材料科学，生物学和医学等领域现代科学研究中必不可少的工具。和量子可控性。当前，使用脉冲场是产生高达100 T的高磁场的唯一可控且无损的方法。因此，将NMR与脉冲场结合起来被认为具有广泛的潜力，可用于多种科学和技术学科。不管最重要的技术挑战，包括脉冲场的持续时间短，不稳定的高原以及不良的场均一性和可重复性，德国，法国，和日本。在本文中，我们简要回顾了脉冲场NMR技术的现状及其在多个学科中的应用。我们还讨论了有关脉冲场NMR升级的未来趋势。