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用于有机和无机材料无损表征的核磁共振传感器。

H NMR Sensor for Nondestructive Characterization of Organic and Inorganic Materials.

作者信息

Díaz-Díaz Floriberto, Cano-Barrita Prisciliano F de J, León-Martínez Frank M, Acevedo-Arzola Víktor

机构信息

Instituto Politécnico Nacional/CIIDIR Unidad Oaxaca, Calle Hornos No. 1003, Col. Noche Buena, Santa Cruz Xoxocotlán, Oaxaca 71230, Mexico.

Conahcyt-Instituto Politécnico Nacional/CIIDIR Unidad Oaxaca, Calle Hornos No. 1003, Col. Noche Buena, Santa Cruz Xoxocotlán, Oaxaca 71230, Mexico.

出版信息

Sensors (Basel). 2024 Nov 30;24(23):7692. doi: 10.3390/s24237692.

DOI:10.3390/s24237692
PMID:39686229
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11644910/
Abstract

Nuclear magnetic resonance relaxation of the proton spins of liquid molecules and their evolution during processes such as drying, fluid flow, and phase change of a sample can be monitored in a nondestructive way. A unilateral H NMR sensor made with a permanent magnet array, inspired by the NMR MOUSE, with an RF coil tuned to 11.71 MHz was developed. This creates a sensitive homogeneous measuring volume parallel to the sensor surface and located 14 mm from its surface, allowing contactless measurements from the sample's interior. As this sensitive volume is moved across the sample using a semi-automatic linear displacement mechanism with millimetric precision, spatial T lifetime and signal intensity 1D profiles can be obtained. To characterize the sensor's sensitive volume, eraser samples were used. To evaluate the sensor's ability to characterize different materials, cement paste samples containing ordinary and white Portland cement were prepared and measured at seven days of age. In addition, measurements were made on organic samples such as a Hass avocado and beef steak. Based on the results, a 1 mm spatial resolution of the sensor was achieved. The sensor was able to detect differences in T lifetimes in eraser specimens composed of layers of three different erasers. Also, a clear difference in T lifetimes and signal intensities was observed in cement pastes composed of white and ordinary Portland cement. On the other hand, it was possible to obtain signals from the peel and pulp of the avocado fruit, as well as from the fat and meat in a beef steak in a nondestructive way. The T lifetimes of the different materials agreed with those obtained using a commercial NMR spectrometer.

摘要

液体分子中质子自旋的核磁共振弛豫及其在干燥、流体流动和样品相变等过程中的演变可以通过无损方式进行监测。受核磁共振小鼠(NMR MOUSE)启发,开发了一种由永磁体阵列制成的单边核磁共振传感器,其射频线圈调谐至11.71 MHz。这在与传感器表面平行且距离其表面14 mm处创建了一个灵敏的均匀测量体积,从而能够对样品内部进行非接触式测量。当使用具有毫米精度的半自动线性位移机构使这个灵敏体积在样品上移动时,就可以获得空间T弛豫时间和信号强度的一维分布图。为了表征传感器的灵敏体积,使用了橡皮擦样品。为了评估传感器表征不同材料的能力,制备了含有普通波特兰水泥和白色波特兰水泥的水泥净浆样品,并在其龄期为7天时进行测量。此外,还对哈斯牛油果和牛排等有机样品进行了测量。根据测量结果,该传感器实现了1 mm的空间分辨率。该传感器能够检测由三种不同橡皮擦层组成的橡皮擦样品中T弛豫时间的差异。同样,在由白色波特兰水泥和普通波特兰水泥组成的水泥净浆中,也观察到了T弛豫时间和信号强度的明显差异。另一方面,能够以无损方式从鳄梨果实的果皮和果肉以及牛排中的脂肪和肉中获取信号。不同材料的T弛豫时间与使用商用核磁共振光谱仪获得的结果一致。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1de9/11644910/95444bde43a8/sensors-24-07692-g007.jpg
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