Investigating polymer crystallization at the nanoscale using AFM-IR

使用 AFM-IR 研究纳米级聚合物结晶

• 批准号: RGPIN-2020-06212
• 负责人: NguyenTri, Phuong
• 金额: $ 2.04万
• 依托单位: Université du Québec à Trois-Rivières
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=748767
• 关键词: Investigating; polymer; crystallization; nanoscale; using

Controlling the morphology and crystallization of polymers and composites is crucial because it is directly related to the final properties of the material. Semi-crystalline polymers are an important fraction of commercial polymers. It is well known that miscible polymeric blends can have a variety of morphologies and crystallization mechanisms that depend on the difference in the melting temperature of each component, the blend composition and the crystallization conditions. These phenomena become more complex in the binary blends of miscible and crystallizable polymers where the two components are in competition to reach the final structure (e.g. shape, orientation, morphology, topography, texture and density). However, the examination of the distribution of polymers in crystallizable polymer blends, especially at the submicron scale, is technically difficult despite the progress of the physicochemical characterization methods. Recently, we have been able to use an advanced equipment, i.e. atomic force microscopy-infrared spectroscopy (AFM-IR), to study the crystallization and nano-diffusion of polymers in miscible and immiscible blends, while recording their high-resolution topographic images at the nanoscale level. This advancement was made possible through the ability to qualitatively identify the chemical composition of the compound through AFM-IR. The preliminary results have led to several publications and awards. In this research program, we will develop new approaches to better understand the miscibility, crystallization and distribution of biodegradable polymers, particularly the binary polymeric blends at the nanoscale level using mainly atomic force microscopy coupled with an infrared spectroscopy (AFM-IR) or a thermocouple (Nano-TA). The simulation of the dynamics of the polymer blends will be carried out in order to understand the molecular structure during the crystallization using mainly the Large-scale Atomic/Molecular Massively Parallel Simulator (LAMMPS) Molecular Dynamics Simulator software dedicated to polymers and biomolecules. Nanoscale characterization methods help to better answer the open questions in the literature, particularly the molecular arrangements, lamella development mechanisms, morphology and phase transition in a spherical structure that are more important features to detect the final behavior of biopolymer materials. Understanding the diffusion of polymers in relation to the structure of spherulites and the operating conditions in polymer blends will provide an important scientific contribution and open a new pathway for crystallization studies in complex systems, such as ternary and quaternary blends. Improving the properties of the polymer blends will extend the field of use of these biopolymers in various applications such as in biomedical materials and biological tissues (globally, market of US$25.4 billion for 2019).

控制聚合物和复合材料的形态和结晶至关重要，因为它直接关系到材料的最终性能。半结晶聚合物是商品聚合物的重要组成部分。众所周知，可混溶的聚合物共混物可以有不同的形态和结晶机制，这取决于每种组分的熔融温度、共混物组成和结晶条件的不同。这些现象在可混溶和可结晶聚合物的二元共混物中变得更加复杂，其中两个组分竞争以获得最终结构(例如形状、取向、形态、形貌、纹理和密度)。然而，尽管物理化学表征方法取得了进展，但研究聚合物在可结晶聚合物共混物中的分布，特别是亚微米级的聚合物分布，在技术上是困难的。近年来，我们已经能够利用先进的原子力显微镜-红外光谱(AFM-IR)来研究聚合物在可混溶和不相容共混物中的结晶和纳米扩散，同时在纳米尺度上记录其高分辨率的形貌图像。这一进展是通过AFM-IR定性鉴定化合物的化学成分而实现的。初步结果已经导致了几份出版物和奖项。在这项研究计划中，我们将开发新的方法来更好地了解可生物降解聚合物的相容性、结晶和分布，特别是纳米级的二元聚合物共混物，主要使用原子力显微镜结合红外光谱(AFM-IR)或热电偶(Nano-TA)。为了了解结晶过程中的分子结构，将主要使用大型原子/分子大规模并行模拟器(LAMMPS)分子动力学模拟器软件对聚合物共混物的动力学进行模拟，该软件专门用于聚合物和生物分子。纳米尺度的表征方法有助于更好地回答文献中的开放问题，特别是球形结构中的分子排列、片层发育机制、形态和相变等更重要的特征，这些特征是检测生物聚合物材料最终行为的更重要特征。了解聚合物在共混体系中的扩散与球晶结构和操作条件的关系，将为三元和四元共混等复杂体系的结晶研究提供重要的科学贡献和开辟一条新的途径。聚合物共混物性能的提高将扩大这些生物聚合物在各种应用中的使用领域，例如在生物医学材料和生物组织中(2019年全球市场规模为254亿美元)。