木材中水分分布及其存在状态研究进展

doi:10.11707/j.1001-7488.20171016

摘要/Abstract

摘要： 木材-水分关系是木材科学领域的传统经典研究内容。随着现代分析技术不断发展，木材-水分关系研究已从宏观进入到微观，从细胞水平上升到分子水平，趋向于系统化和综合性。本文首先论述木材细胞壁壁层结构与化学组分的非均匀性以及木材中水分存在状态的多样性，得出木材-水分关系研究的热点和难点是木材中水分分布以及存在状态。其次，归纳磁共振成像、计算机断层扫描成像、中子成像和振动光谱成像4种现代分析技术应用于木材中水分分布研究的最新进展，并分析这4种技术的优缺点。其中，部分最新研究进展是：属于振动光谱成像的显微红外成像技术具有6.25 μm的空间分辨率，可用于木材细胞壁水分分布研究，结果证实纤维饱和点以下木材细胞壁中水分分布具有不均匀性；而同属于振动光谱成像的显微拉曼成像技术具有1 μm的空间分辨率，适用于木材细胞壁不同形态区水分分布研究，结果证实在纤维饱和点以下木材次生壁中层的含水量高于细胞角隅区。再次，总结近红外光谱、磁共振、红外光谱、拉曼光谱4种分析技术应用于木材中水分存在状态研究的最新进展，并分析这4种技术的优缺点。其中，部分最新研究进展是：木材中水分吸附的主要活性位点是羟基和羰基；纤维饱和点以下木材中吸着水的存在状态为强氢键结合水、中等氢键结合水和弱氢键结合水；根据3种状态水随相对湿度的变化趋势，可将木材中水分吸附过程分为3个阶段，每个阶段所吸附水的分子结构主要为C=O…（HOH）…OH或OH…（OH₂）…OH、WATER…HOH…WATER以及四面体结构。最后，本文指出木材中水分分布及其存在状态尚有许多疑问亟待解答，应以研发更高精度、更高灵敏度的分析技术以及更可信的谱图成分分析技术为突破口，在细胞水平、分子水平上深入揭示木材-水分关系。

关键词: 木材, 水分分布, 存在状态

Abstract: Wood-water relationship has been studied since the beginning of wood research. With the development of new technology, vast modern analytical method are emerging, and the study of wood-water relationship is changing from macro to micro scale and from cell to molecular level. The main objective of this paper was to review the modern analytical techniques which have been applied to study the wood-water relationship. This paper was divided into four parts. Firstly, the extremely heterogeneity of the wood cell wall structure and chemical composition and the highly complex states of water were discussed, and then the distribution and existing states of water in wood was summarized as an active field of the research about wood-water relationship. Secondly, the application of four kinds of analytical techniques, such as magnetic resonance imaging (MRI), computed tomography (CT), neutron imaging (NI) and vibrational spectroscopic imaging, in the study of water distribution were summarized. Meanwhile, the advantages and limitations of these four techniques were provided. Some of the latest research progress was:Vibrational spectroscopic imaging techniques such as micro-FTIR and confocal Raman could offer visual examination and spectral information of chemical functional groups in situ, and owned high spatial resolution on the micrometer length scale. The spatial resolution of micro-FTIR imaging technique was 6.25 μm by the instrumental parameters, and the spectral changes indicated that the adsorbed water concentration was nonuniform at the cell structure level. Meanwhile, the spatial resolution of confocal Raman imaging technique was higher than 1 μm, and the spectral changes indicated that the amount of water in the cell corner (CC) was less than that in the middle layer of secondary wall (S2) throughout the entire range of relative humidity (RH) levels. Thirdly, the recent advances in the application of four kinds of analytical techniques, such as near infrared (NIR) spectroscopy, nuclear magnetic resonance (NMR), fourier transform infrared spectroscopy (FTIR) and Raman spectroscopy, were discussed in the study of existing states of water in wood. The advantages and limitations of these four techniques were also provided. Some of the latest research progress was:The micro-FTIR spectroscopy and a specially designed sample cell were used to examine the molecular association of adsorbed water with wood during adsorption process. It was confirmed that carboxyl C=O, C-O groups as well as OH groups were active sites for water adsorption. Meanwhile, strongly, moderately and weakly hydrogen-bonded water molecules were identified and assigned. What's more, according to the variation trend of these hydrogen-bonded water molecules, three sections were divided for adsorption process. Furthermore, the existing states of water in each section was demonstrated as C=O…(HOH)…OH or OH…(OH₂)…OH、WATER…HOH…WATER, and tetrahedral structure. Finally, some future research subjects in the research about wood-water relationship were proposed, such as applying new approaches with greater accuracy and higher resolution, developing the convincing component band analysis.

Key words: wood, water distribution, existing states

中图分类号:

S781.33

郭鑫, 吴义强, 李贤军. 木材中水分分布及其存在状态研究进展[J]. 林业科学, 2017, 53(10): 146-153.

Guo Xin, Wu Yiqiang, Li Xianjun. Distribution and Existing States of Water in Wood:A Review[J]. Scientia Silvae Sinicae, 2017, 53(10): 146-153.

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