Conservation of model degraded pine wood with selected organosilicons studied by XFM and nanoindentation

IF 3.1 2区农林科学 Q1 FORESTRY

Wood Science and Technology Pub Date : 2024-02-10 DOI:10.1007/s00226-024-01533-6

Magdalena Broda, Joseph E. Jakes, Luxi Li, Olga A. Antipova, Evan R. Maxey, Qiaoling Jin

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Abstract

Previous research found that some organosilicon treatments proved effective in stabilizing waterlogged wood dimensions during drying. The present research aimed to determine the mechanism of wood stabilization by these chemicals to understand their mode of action. The study used chemically (ChP) and biologically degraded (BP) model Scots pine wood treated with Methyltrimethoxysilane (MTMS), (3-Mercaptopropyl) trimethoxysilane (MPTMS), or 1,3-Bis(diethylamino)-3-propoxypropanol)-1,1,3,3-tetramethyldisiloxane (DEAPTMDS). Synchrotron-based X-ray fluorescence microscopy (XFM) was used to investigate the penetration of organosilicons into the wood cellular structure and cell walls, and nanoindentation was used to study the mechanical properties of the treated wood cell walls. All treatments resulted in high volumetric anti-shrink efficiency (ASE_V) values of 74–82%, except for MTMS-treated ChP with an ASE_V of 52%. The multiscale XFM results revealed that all applied organosilicons penetrated throughout the whole wooden blocks and deposited in both cell lumina and cell walls. The retention of all applied organosilicons was highest in BP wood, and so was the dimensional stabilization effect. MTMS-treated ChP had the lowest measured cell wall infiltration, which likely contributed to its lower ASE_v. DEAPTMDS treatments plasticized the cell walls and resulted in lowered nanoindentation elastic modulus (E_s^NI) and hardness (H) for all types of wood. MTMS and MPTMS had modest effects on cell wall mechanical properties, and the effect depended on the type of wood. The final effect of organosilicon treatment on the dimensional wood stabilization and mechanical properties of wood cell walls depended not only on the type of the applied organosilicon but also the type of wood degradation. This means that the treatment cannot be considered universal, and specific approaches are needed for the conservation of individual wooden objects. Although some mechanisms are now better understood, such as the need for organosilicons to infiltrate the cell walls and the plasticizing effect of DEAPTMDS, other aspects will benefit from a more detailed analysis of the molecular interactions between organosilicons and wood polymers.

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用 XFM 和纳米压痕法研究模型降解松木与特定有机硅的保护作用

以前的研究发现，一些有机硅处理剂在干燥过程中能有效稳定水渍木材的尺寸。本研究旨在确定这些化学品稳定木材的机理，以了解其作用模式。研究使用了经甲基三甲氧基硅烷（MTMS）、（3-巯丙基）三甲氧基硅烷（MPTMS）或 1,3-双（二乙胺基）-3-丙氧基丙醇）-1,1,3,3-四甲基二硅氧烷（DEAPTMDS）处理的化学降解（ChP）和生物降解（BP）模型苏格兰松木。同步辐射 X 射线荧光显微镜（XFM）用于研究有机硅对木材细胞结构和细胞壁的渗透，纳米压痕法用于研究处理过的木材细胞壁的机械性能。除 MTMS 处理的 ChP 的 ASEV 值为 52% 外，所有处理的体积抗收缩效率 (ASEV) 值均高达 74-82%。多尺度 XFM 结果显示，所有施用的有机硅都渗透到整个木块中，并沉积在细胞膜和细胞壁中。所有施用的有机硅在 BP 木材中的保留率最高，尺寸稳定效果也最高。经 MTMS 处理的 ChP 的细胞壁浸润度最低，这可能是其 ASEv 较低的原因。DEAPTMDS 处理使细胞壁塑化，导致所有类型木材的纳米压痕弹性模量（EsNI）和硬度（H）降低。MTMS 和 MPTMS 对细胞壁机械特性的影响不大，其影响取决于木材的类型。有机硅处理对木材尺寸稳定性和木材细胞壁力学性能的最终影响不仅取决于所应用的有机硅类型，还取决于木材降解的类型。这意味着有机硅处理不能被认为是普遍适用的，需要针对不同的木制物品采取特定的保护方法。虽然现在对某些机理有了更深入的了解，例如有机硅渗入细胞壁的必要性和 DEAPTMDS 的塑化效果，但对有机硅和木材聚合物之间的分子相互作用进行更详细的分析将有助于其他方面的研究。

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来源期刊

Wood Science and Technology 工程技术-材料科学：纸与木材

CiteScore

5.90

自引率

5.90%

发文量

审稿时长

3 months

期刊介绍： Wood Science and Technology publishes original scientific research results and review papers covering the entire field of wood material science, wood components and wood based products. Subjects are wood biology and wood quality, wood physics and physical technologies, wood chemistry and chemical technologies. Latest advances in areas such as cell wall and wood formation; structural and chemical composition of wood and wood composites and their property relations; physical, mechanical and chemical characterization and relevant methodological developments, and microbiological degradation of wood and wood based products are reported. Topics related to wood technology include machining, gluing, and finishing, composite technology, wood modification, wood mechanics, creep and rheology, and the conversion of wood into pulp and biorefinery products.