增强物理和电化学性能的分层聚酰亚胺-共价有机框架碳纤维结构

Piers Coia, Bhagya Dharmasiri, David J. Hayne, Ameya Borkar, Carol Hua, Elmer Austria, Behnam Akhavan, Mia Angela Nuñeza Judicpa, Ken Aldren Sumaya Usman, Joselito Razal, Luke C. Henderson
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引用次数: 0

摘要

人们正在广泛探索碳纤维(CF)的多功能性。在这里,聚酰亚胺共价有机框架(PI-COF)被接枝到碳纤维上,以增强其机械和电化学性能。在这里,一系列 COF 支架通过两步功能化接枝到 CF 表面。首先,将三聚氰胺拴在纤维表面,为 COF 提供一个锚定点,然后采用 "接枝 "方法,利用三种不同大小的二酸酐(PMDA 形成 MA-PMDA,NTCDA 形成 MA-NTCDA,PTCDA 形成 MA-PTCDA COF)生长出三种不同大小的 PI-COF。这些 COFs 使 MA-PTCDA 的 CF 电容最大增加了 2.9 F g-1(增加了 480%),同时 MA-NTCDA 和 MA-PTCDA 的界面剪切强度也分别增加了 67.5% 和 52%。这些数据表明,PI-COF 首次对 CF 进行了改性,使 COF 在附着于基底的同时,还具有多孔性和二氧化碳捕获能力等特性。这可能会为 CF 带来更多高价值的可回收性和二次生命应用。
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Hierarchical Polyimide-Covalent Organic Frameworks Carbon Fiber Structures Enhancing Physical and Electrochemical Properties
The multifunctionality of carbon fiber (CF) is being extensively explored. Herein, polyimide covalent organic frameworks (PI-COFs) are grafted bound to CF to enhance their mechanical and electrochemical properties. Here, a range of COF scaffolds are grafted to the surface of CFs via a two-step functionalization. First, melamine is tethered to the fiber surface to provide an anchoring point for the COFs followed by a “graft from” approach to grow three different sized PI-COFs utilizing three differently sized dianhydride, PMDA to form MA-PMDA, NTCDA to form MA-NTCDA, and PTCDA to form MA-PTCDA COFs. These COFs increase the capacitance of CF by a maximum of 2.9 F g−1 (480% increase) for the MA-PTCDA, this coincides with an increase in interfacial shear strength by 67.5% and 52% for MA-NTCDA and MA-PTCDA, respectively. This data represents that the first-time CF has been modified with PI-COFs and allows access to COF properties including their porosity and CO2 capture ability while being attached to a substrate. This may lead to additional high-value recyclability and second-life applications for CFs.
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