AI Article Synopsis
- Single-sided NMR systems are gaining popularity in labs and industries due to their affordability and ability to analyze hydrogen-based materials.
- Recent advancements have improved their performance in terms of field strength and homogeneity, yet some designs may compromise these qualities, affecting diffusion measurement.
- The study proposes a novel method to adapt diffusion-editing techniques for NMR devices with inhomogeneous magnetic fields, utilizing a custom diffusion kernel to enhance analysis of multi-phasic fluids.
Article Abstract
Single-sided NMR systems are becoming a relevant tool in industry and laboratory environments due to their low cost, low maintenance and capacity to evaluate quantity and quality of hydrogen based materials. The performance of such devices has improved significantly over the last decade, providing increased field homogeneity, field strength and even controlled static field gradients. For a class of these devices, the configuration of the permanent magnets provides a linear variation of the magnetic field and can be used in diffusion measurements. However, magnet design depends directly on its application and, according to the purpose, the field homogeneity may significantly be compromised. This may prevent the determination of diffusion properties of fluids based on the natural inhomogeneity of the field using known techniques. This work introduces a new approach that extends the applicability of diffusion-editing CPMG experiments to NMR devices with highly inhomogeneous magnetic fields, which do not vary linearly in space. Herein, we propose a method to determine a custom diffusion kernel based on the gradient distribution, which can be seen as a signature of each NMR device. This new diffusion kernel is then utilised in the 2D inverse Laplace transform (2D ILT) in order to determine diffusion-relaxation correlation maps of homogeneous multi-phasic fluids. The experiments were performed using NMR MObile Lateral Explore (MOLE), which is a single-sided NMR device designed to maximise the volume at the sweet spot with enhanced depth penetration.
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| http://dx.doi.org/10.1016/j.jmr.2014.07.012 | DOI Listing |
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