Determination of nuclear magnetic resonance surface relaxivity for the macropore system from wood cell lumen

IF 2.2 3区农林科学 Q2 FORESTRY

Journal of Wood Science Pub Date : 2024-01-11 DOI:10.1186/s10086-023-02117-x

Zhi Jin, Yuejin Fu, Qian Chen, Zhen Zeng

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引用次数: 0

Abstract

To determine the surface relaxivity of pores plays a vital role in the application of time-domain nuclear magnetic resonance (TD-NMR) technology to porous structure characterization for wood. Currently, the surface relaxivity of pores is calibrated using a standard sample with a pore size of the same order as the wood pore system. However, the uniformly distributed pore size of standard sample is unfit to accurately indicate the complexity of porous structure of wood, which significantly affects the accuracy of test results. By integrating the TD-NMR technology with mercury intrusion porosimetry (MIP), the surface relaxivity of macropores in the lumen of wood cells is calibrated in this study using the tested sample, so as to avoid the error in measurement as caused by existing method. Data processing is performed using several mathematical methods including interpolation arithmetic and least square principle. Notably, the node segmentation method is applied to identify the T2 boundary of pores in cell lumen and to classify the porous structure of cell lumen into different pore systems. The approach proposed in this study is demonstrated to be effective in improving the accuracy of TD-NMR technology for characterizing the porous structure of wood. Also, it contributes a potential solution to accounting for the porous structure of wood based on the phenomenon of pore relaxation, which can improve the understanding of wood pore conformation.

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测定木材细胞腔大孔系统的核磁共振表面弛豫性

在应用时域核磁共振 (TD-NMR) 技术进行木材多孔结构表征时，确定孔隙的表面弛豫度起着至关重要的作用。目前，孔隙表面弛豫度是使用孔隙大小与木材孔隙系统相同的标准样品进行校准的。然而，标准样品均匀分布的孔隙尺寸无法准确显示木材多孔结构的复杂性，从而严重影响了测试结果的准确性。本研究将 TD-NMR 技术与汞侵入孔隙比色法（MIP）相结合，利用测试样品对木材细胞腔内大孔的表面弛豫度进行校准，从而避免了现有方法造成的测量误差。数据处理采用多种数学方法，包括插值算术和最小平方原理。值得注意的是，节点分割法用于识别细胞腔中孔隙的 T2 边界，并将细胞腔的多孔结构划分为不同的孔隙系统。本研究提出的方法证明能有效提高 TD-NMR 技术表征木材多孔结构的准确性。此外，它还为基于孔隙弛豫现象来解释木材的多孔结构提供了一种潜在的解决方案，可提高人们对木材孔隙构象的认识。

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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来源期刊

Journal of Wood Science 工程技术-材料科学：纸与木材

CiteScore

5.40

自引率

10.30%

发文量

审稿时长

6 months

期刊介绍： The Journal of Wood Science is the official journal of the Japan Wood Research Society. This journal provides an international forum for the exchange of knowledge and the discussion of current issues in wood and its utilization. The journal publishes original articles on basic and applied research dealing with the science, technology, and engineering of wood, wood components, wood and wood-based products, and wood constructions. Articles concerned with pulp and paper, fiber resources from non-woody plants, wood-inhabiting insects and fungi, wood biomass, and environmental and ecological issues in forest products are also included. In addition to original articles, the journal publishes review articles on selected topics concerning wood science and related fields. The editors welcome the submission of manuscripts from any country.