Tabletop Scanning Electron Microscope (SEM) for Advancing Research in Characterization and Assessment of the Properties and Long-Term Performance of Innovative FRP Materials and Bio-based Composites

台式扫描电子显微镜 (SEM) 用于推进创新 FRP 材料和生物基复合材料的特性和长期性能表征和评估研究

• 批准号: RTI-2022-00255
• 负责人: Benmokrane, Brahim
• 金额: $ 10.91万
• 依托单位: Université de Sherbrooke
• 依托单位国家: 加拿大
• 项目类别: Research Tools and Instruments
• 财政年份: 2021
• 资助国家: 加拿大
• 起止时间: 2021-01-01 至 2022-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=743047
• 关键词: Tabletop; Scanning; Electron; Microscope; SEM

Fiber-reinforced polymers (FRPs) are being used increasingly as internal reinforcement in concrete structures as a cost-effective alternative to conventional steel bars. Given their corrosion resistance, light weight, and high strength, FRP bars have been used in Canada for the last 30 years for infrastructure such bridge decks, parking garages, and continuous pavements. Despite research and product certification, FRP durability-especially under severe environmental conditions-stands out as the most critical research topic. The lack of appropriate data about the long-term durability poses a major obstacle to broader acceptance and mass implementation of FRPs. To address this concern, the applicants are conducting research programs investigating the effects of various physical/environmental/load/synergetic parameters on the long-term performance of new advanced materials and FRP products incorporating a new class of fibers (glass, basalt, and natural fibers), resin systems with low diffusion/permeability (vinyl-ester, epoxy, polyurethane, acrylic, and biosourced resins), and new nanomaterials (nanocellulose and carbon nanoparticles). The applicants' research activities include the determination of fundamental properties of control (unconditioned) and conditioned (environmental exposure, loaded) FRP samples to assess degradation mechanisms (i.e., fiber dominated, matrix dominated, and interface dominated) and FRP penetration by moisture or chemical solutions (such as alkaline concrete). In particular, the durability performance of the interface will be monitored using a Tabletop Scanning Electron Microscope (SEM) coupled with Energy-Dispersive X-ray Spectroscopy (EDS). Moreover, projects involving the use of natural fibers or resins in ecocomposites will strongly benefit from this equipment for characterizing natural fiber surface modification and bonding, surface microstructure, properties of reinforcing materials, and interphase/interface behavior, with the objective to develop materials with improved properties and durability. Moreover, our new projects (Tier1 and Tier2 CRC of the co-applicants) involving natural fibers or biosourced resins in ecocomposites will strongly benefit from this equipment for characterizing resin surface modification, surface microstructure and properties of reinforcing materials and interphase/interface behaviour of materials subjected to moist environments and aggressive media. The proposed research will (1) provide new knowledge into the factors controlling the durability of FRPs containing a new class of fibers and resins, modified natural fibers, and nanomaterials such as carbon nanotubes; (2) provide reliable models to predict the service life; and (3) influence upcoming FRP codes and specifications. 27 HQP (17 PhD, 5 MASc, 3 PDF and 2 technicians) will receive advanced training on FRPs and nanomaterials on this equipment. The requested equipment will be used in accordance with NSERC's Statements on EDI.

纤维增强聚合物 (FRP) 越来越多地用作混凝土结构的内部钢筋，作为传统钢筋的经济高效替代品。由于 FRP 筋耐腐蚀、重量轻、强度高，过去 30 年加拿大一直将 FRP 筋用于桥面、停车场和连续路面等基础设施。尽管进行了研究和产品认证，但玻璃钢的耐久性——尤其是在恶劣的环境条件下——仍然是最关键的研究课题。缺乏有关长期耐久性的适当数据对玻璃钢的更广泛接受和大规模实施构成了主要障碍。为了解决这个问题，申请人正在开展研究项目，调查各种物理/环境/负载/协同参数对采用新型纤维（玻璃、玄武岩和天然纤维）的新型先进材料和 FRP 产品的长期性能的影响。纤维）、低扩散/渗透性树脂系统（乙烯基酯、环氧树脂、聚氨酯、丙烯酸和生物来源树脂）以及新型纳米材料（纳米纤维素和碳纳米颗粒）。申请人的研究活动包括确定控制（无条件）和条件（环境暴露、负载）FRP 样品的基本特性，以评估降解机制（即纤维主导、基体主导和界面主导）以及湿气或化学物质对 FRP 的渗透溶液（如碱性混凝土）。特别是，将使用台式扫描电子显微镜 (SEM) 与能量色散 X 射线光谱 (EDS) 相结合来监测界面的耐久性能。此外，涉及在生态复合材料中使用天然纤维或树脂的项目将极大地受益于该设备，用于表征天然纤维表面改性和粘合、表面微观结构、增强材料的性能以及界面/界面行为，目的是开发具有改进性能的材料。性能和耐用性。此外，我们涉及生态复合材料中的天然纤维或生物来源树脂的新项目（共同申请人的 Tier1 和 Tier2 CRC）将极大地受益于该设备，用于表征树脂表面改性、增强材料的表面微观结构和性能以及材料的界面/界面行为受到潮湿环境和腐蚀性介质的影响。拟议的研究将（1）为控制含有新型纤维和树脂、改性天然纤维以及碳纳米管等纳米材料的 FRP 耐久性的因素提供新的知识； (2)提供可靠的模型来预测使用寿命； (3) 影响即将出台的 FRP 规范和规范。 27 名总部人员（17 名博士、5 名硕士、3 名 PDF 和 2 名技术人员）将在该设备上接受有关 FRP 和纳米材料的高级培训。所请求的设备将根据 NSERC 的 EDI 声明使用。