Hierarchical Polyimide-Covalent Organic Frameworks Carbon Fiber Structures Enhancing Physical and Electrochemical Properties

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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Abstract

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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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
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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