Unilateral RF sensors based on parallel-plate architecture for improved surface-scan MRI analysis of commercial pouch cells

IF 2.624
Konstantin Romanenko , Nikolai Avdievich
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引用次数: 0

Abstract

Rapid expansion of the Li-ion pouch cell market is driven by the looming problem of permanent depletion of natural gas reservoirs and by the growing demand for high-performance portable devices and electric vehicles. Safety and performance of Li-ion cells have been two main focal points of the extensive battery research. Surface-scan Magnetic Resonance Imaging (MRI) is an operando method designed for the accurate detection of substandard battery cells and for monitoring electrochemical processes with high spatial and temporal resolutions. Intercalation-dependent magnetism and charge transfer processes in the cell's electrodes give rise to characteristic magnetic field patterns outside the cell. For accurate mapping of such patterns, we proposed the concept of a unilateral radio-frequency (RF) sensor, a flat thin resonator encapsulating a proton-rich solid-state detection medium. When the pouch cell is placed in direct contact with the sensor, the magnetic field patterns propagate inside the detection medium, and the corresponding spatial distribution of Larmor precession frequencies can be detected with MRI. In this work, we developed and evaluated a series of RF sensor configurations based on parallel-plate architecture enhanced by arrays of distributed capacitors. The parallel-plate approach does not suffer from RF interference with pouch cells and provides excellent sensitivity and B1-field homogeneity. The optimal configuration of the parallel-plate sensor depends on the dimensions of the pouch cell and the distribution of parallel capacitors. This article includes the results of experimental tests, RF-field simulations, and strategies to further improve the surface-scan MRI method.

Abstract Image

Abstract Image

基于平行板结构的单侧射频传感器,用于改进商业小袋细胞的表面扫描磁共振成像分析
锂离子袋装电池市场的快速扩张是受到天然气储藏永久枯竭问题迫在眉睫以及高性能便携设备和电动汽车需求不断增长的推动。锂离子电池的安全性和性能一直是广泛电池研究的两大焦点。表面扫描磁共振成像(MRI)是一种操作方法,旨在准确检测不合格电池,并以高空间和时间分辨率监测电化学过程。电池电极中依赖于互锁的磁性和电荷转移过程会在电池外部产生特征磁场模式。为了精确绘制这种模式,我们提出了单侧射频(RF)传感器的概念,即一个封装了富质子固态检测介质的扁平薄型谐振器。当小袋细胞与传感器直接接触时,磁场模式会在传感器的检测介质内传播,相应的拉莫尔前冲频率的空间分布可以通过核磁共振成像检测到。在这项工作中,我们开发并评估了一系列基于平行板结构的射频传感器配置,并通过分布式电容器阵列进行了增强。平行板方法不会受到小袋细胞的射频干扰,并具有出色的灵敏度和 B1 场均匀性。平行板传感器的最佳配置取决于邮袋电池的尺寸和平行电容器的分布。本文包括实验测试结果、射频场模拟以及进一步改进表面扫描磁共振成像方法的策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
1.90
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