The role of lignin as interfacial compatibilizer in designing lignocellulosic-polyester composite films

IF 9.4 1区 化学 Q1 CHEMISTRY, PHYSICAL
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Abstract

Advancing nanocomposites requires a deep understanding and careful design of nanoscale interfaces, as interfacial interactions and adhesion significantly influence the physical and mechanical properties of these materials. This study demonstrates the effectiveness of lignin nanoparticles (LNPs) as interfacial compatibilizer between hydrophilic cellulose nanofibrils (CNF) and a hydrophobic polyester, polycaprolactone (PCL). In this context, we conducted a detailed analysis of surface-to-bulk interactions in both wet and dry conditions using advanced techniques such as quartz crystal microbalance with dissipation (QCM-D), atomic force microscopy (AFM), water contact angle (WCA) measurements, broadband dielectric spectroscopy (BDS), and inverse gas chromatography (IGC).
QCM-D was employed to quantify the adsorption behavior of LNPs on CNF and PCL surfaces, demonstrating LNPs’ capability to interact with both hydrophilic and hydrophobic phases, thereby enhancing composite material properties. LNPs showed extensive adsorption on a CNF model film (1186 ± 178 ng.cm−2) and a lower but still significant adsorption on a PCL model film (270 ± 64 ng.cm−2). In contrast, CNF adsorption on a PCL model film was the lowest, with a sensed mass of only 136 ± 35 ng.cm−2. These findings were further supported by comparing the morphology and wettability of the films before and after adsorption, using AFM and WCA analyses. Then, to gain insights into the molecular-level interactions and molecular mobility within the composite in dry state, BDS was employed. The BDS results showed that LNPs improved the dispersion of PCL within the CNF network. To further investigate the impact of LNPs on the composites’ interfacial properties, IGC was employed. This analysis showed that the composite films containing LNPs exhibited lower surface energy compared to those composed of only CNF and PCL. The presence of LNPs likely reduced the availability of surface hydroxyl groups, thus modifying the physicochemical properties of the interface. These changes were particularly evident in the heterogeneity of the surface energy profile, indicating that LNPs significantly altered the interfacial characteristics of the composite materials.
Overall, these findings emphasize the necessity to control the interfaces between components for next-generation nanocomposite materials across diverse applications.

Abstract Image

木质素作为界面相容剂在设计木质纤维素-聚酯复合薄膜中的作用。
要推进纳米复合材料的发展,就必须深入了解并精心设计纳米级界面,因为界面相互作用和附着力会极大地影响这些材料的物理和机械性能。本研究证明了木质素纳米颗粒(LNPs)作为亲水性纤维素纳米纤维(CNF)和疏水性聚酯聚己内酯(PCL)之间的界面相容剂的有效性。在这种情况下,我们采用先进的技术,如带耗散的石英晶体微天平 (QCM-D)、原子力显微镜 (AFM)、水接触角 (WCA) 测量、宽带介电光谱 (BDS) 和反气相色谱法 (IGC),详细分析了湿和干条件下表面与聚合物之间的相互作用。QCM-D 被用来量化 LNPs 在 CNF 和 PCL 表面上的吸附行为,证明 LNPs 能够与亲水相和疏水相相互作用,从而增强复合材料的性能。LNPs 在 CNF 模型薄膜上的吸附量很大(1186 ± 178 ng.cm-2),而在 PCL 模型薄膜上的吸附量较小,但仍很显著(270 ± 64 ng.cm-2)。相比之下,CNF 在 PCL 模型薄膜上的吸附量最低,感应质量仅为 136 ± 35 ng.cm-2。利用原子力显微镜和 WCA 分析比较了吸附前后薄膜的形态和润湿性,进一步证实了上述发现。然后,为了深入了解干燥状态下复合材料内部的分子水平相互作用和分子流动性,采用了 BDS 方法。BDS 结果表明,LNPs 改善了 PCL 在 CNF 网络中的分散性。为了进一步研究 LNPs 对复合材料界面特性的影响,采用了 IGC 分析法。该分析表明,与仅由 CNF 和 PCL 组成的复合薄膜相比,含有 LNPs 的复合薄膜表现出较低的表面能。LNPs 的存在可能降低了表面羟基的可用性,从而改变了界面的物理化学特性。这些变化在表面能分布的异质性中尤为明显,表明 LNPs 显著改变了复合材料的界面特性。总之,这些发现强调了在各种应用中控制下一代纳米复合材料各组分之间界面的必要性。
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
CiteScore
16.10
自引率
7.10%
发文量
2568
审稿时长
2 months
期刊介绍: The Journal of Colloid and Interface Science publishes original research findings on the fundamental principles of colloid and interface science, as well as innovative applications in various fields. The criteria for publication include impact, quality, novelty, and originality. Emphasis: The journal emphasizes fundamental scientific innovation within the following categories: A.Colloidal Materials and Nanomaterials B.Soft Colloidal and Self-Assembly Systems C.Adsorption, Catalysis, and Electrochemistry D.Interfacial Processes, Capillarity, and Wetting E.Biomaterials and Nanomedicine F.Energy Conversion and Storage, and Environmental Technologies
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