木材细胞壁结构及其流变特性研究进展

doi:10.11707/j.1001-7488.20171215

摘要/Abstract

摘要： 木材流变学主要研究木材在应力/应变、温度、湿度等条件下与时间因素有关的变形规律和机制，以研究木材的黏弹性为主要内容。木材发生形变时，其实质承载结构是细胞壁，细胞壁的壁层构造和化学组分对其黏弹行为有显著影响，深入了解木材细胞壁结构及黏弹性质对于实现木纤维/塑料复合材料和制浆造纸工艺的高效设计具有重要意义。本文围绕木材细胞壁S₂层超微构造和细胞壁化学组分2个方面对细胞壁结构进行阐述，归纳S₂层微纤丝角和化学组分对木材细胞壁黏弹行为的影响规律，并从分子水平上解释其作用机制，总结动态力学分析技术和纳米压痕技术在研究木材细胞壁结构与黏弹性之间关系上的具体应用。木材细胞壁的黏弹性受壁层构造的复杂性、化学组分的多样性和外部环境条件等多种因素影响，并且各因素之间存在一定的交互作用。因此，建议今后从以下几个方面开展研究：1）解明木材细胞生长过程中的微纤丝取向、纤维素结晶区与非结晶区比例的分子控制机制；2）阐明木材细胞壁次生壁Matrix的空间组织排列方式、纤维素聚合体与Matrix之间相互作用的力学行为表达；3）揭示木材细胞壁中半纤维素的含量、种类以及木质素类型对细胞壁黏弹性的影响机制；同时将环境外因（温度、湿度）和载荷类型（静态/动态、拉/压/弯）纳入研究体系，系统揭示"湿-热-力"协同作用下木材细胞壁的机械吸湿蠕变行为规律和响应机制；4）联合运用多种测试技术手段，并引入相关学科的研究方法及理论模型，如有限元法及复合材料的研究方法，构建可以解释木材细胞壁黏弹特性的物理和数学模型。

关键词: 木材, 细胞壁结构, 黏弹性, 流变学

Abstract: Wood rheology is studied mainly focusing on the deformation law and mechanisms of wood under the conditions of stress/strain, temperature, humidity and other circumstances,and its main research field is wood viscoelasticity. The real load-bearing structure of wood is the cell wall, and the structure and chemical composition of cell wall have a significant influence on its viscoelastic behavior. Therefore, having a good comprehension on cell wall structure and viscoelastic properties is of great significance to realize the high efficiency design of wood fiber/plastic composites and pulp and paper manufacturing process. In this paper, the cell wall structure was described from the cell wall S₂ layer and the chemical composition. This paper summarized the influence of S₂ layer microfibril angle and chemical composition on wood cell wall viscoelastic behavior, and the mechanisms of action were explained at the molecular level. In addition, this paper summarized the application of dynamic mechanical analysis (DMA) and nanoindentation techniques on the studies of the relationships between the wood cell wall layer structure and the viscoelasticity. The viscoelasticity of wood cell wall is influenced by the complexity of cell wall structure, diversity of chemical composition and external environmental conditions and other factors, and there are also some interactions among these factors. Therefore, suggestions for future research should be focused on the following aspects:1) To clarify the molecular mechanisms of microfibril orientation and proportion of cellulose crystalline and amorphous region during the growth of wood cells. 2) To illuminate spatial organization arrangement of Matrix in the S\-2 layer of wood cell wall and the expression of the mechanical behavior of the interaction between microfibril and Matrix. 3) To reveal the influence mechanism of content and types of hemicellulose and lignin on cell wall viscoelasticity. At the same time, the external environmental factors (temperature, humidity) and load types (static/dynamic, tension/compression/bending) were brought into the research system to interpret mechano-sorptive creep behavior law and its responsive mechanisms of cell wall, which is under the combined action of "thermo-hydro-mechanical". 4) To utilize various testing techniques, and to introduce the research method and theoretical models of the related disciplines, such as the finite element method and the research method of the composite materials, with the aims to build physical and mathematical models which can explain the viscoelastic properties of wood cell wall.

Key words: wood, cell wall structure, viscoelasticity, rheology

中图分类号:

S781

李安鑫, 吕建雄, 蒋佳荔. 木材细胞壁结构及其流变特性研究进展[J]. 林业科学, 2017, 53(12): 136-143.

Li Anxin, Lü Jianxiong, Jianxiong Jiang. A Review of Wood Cell Wall Structure and Its Rheological Property[J]. Scientia Silvae Sinicae, 2017, 53(12): 136-143.

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