核磁共振用多层哈尔巴赫磁体的设计与仿真

IF 0.9 4区医学 Q4 CHEMISTRY, PHYSICAL

Concepts in Magnetic Resonance Part B-Magnetic Resonance Engineering Pub Date : 2015-08-24 DOI:10.1002/cmr.b.21292

Qiaoyan Chen, Guangcai Zhang, Yajie Xu, Xiaodong Yang

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引用次数: 10

摘要

哈尔巴赫磁铁是一种产生相对高且均匀磁场的永磁体。它适用于小体积化学或生物样品的核磁共振(NMR)研究。本文首次提出了由奇数圆柱层构成的哈尔巴赫磁体模型。然后对奇层Halbach圆柱进行层间距离优化后，以磁体内半径为30 mm、外半径为49 mm为条件进行仿真验证。此外，在5 mm的球面体积直径范围内，存在均匀性扰动，磁场强度和角度变化存在误差。因此，在5 mm DSV内实现了46 ppm的最小均匀性，而在存在磁块误差的情况下，均匀性实际上会增加。奇数层哈尔巴赫磁体的良好性能可能在核磁共振中有潜在的应用。©2015 Wiley期刊公司工程机械学报(自然科学版)，2015,31 (4):554 - 557

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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Design and simulation of a multilayer Halbach magnet for NMR

Halbach magnet is a type of permanent magnet generating a relatively high and homogeneous magnetic field. It is suitable for Nuclear Magnetic Resonance (NMR) studies of small volume chemical or biological samples. In this article, the model of a Halbach magnet made from an odd number of cylindrical layers is proposed for the first time. Then after the optimization of interlayer distances for odd layers Halbach cylinders, the model is verified by the simulation with a magnet inner radius of 30 mm and an outer radius of 49 mm. Moreover, the disturbance of uniformity in 5 mm DSV (Diameter of Spherical Volume) is presented with errors in magnetic strength and angular variation. As a result, a minimum uniformity of 46 ppm inside a 5 mm DSV is achieved, while it increases practically in the presence of magnetic blocks errors. The good performance of the Halbach magnet with odd layers may find potential applications in NMR. © 2015 Wiley Periodicals, Inc. Concepts Magn Reson Part B (Magn Reson Engineering) 45B: 134–141, 2015

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来源期刊

Concepts in Magnetic Resonance Part B-Magnetic Resonance Engineering 物理-光谱学

CiteScore

2.60

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Concepts in Magnetic Resonance Part B brings together engineers and physicists involved in the design and development of hardware and software employed in magnetic resonance techniques. The journal welcomes contributions predominantly from the fields of magnetic resonance imaging (MRI), nuclear magnetic resonance (NMR), and electron paramagnetic resonance (EPR), but also encourages submissions relating to less common magnetic resonance imaging and analytical methods. Contributors come from both academia and industry, to report the latest advancements in the development of instrumentation and computer programming to underpin medical, non-medical, and analytical magnetic resonance techniques.