Encapsulation and on-demand release of functional materials from conductive nanofibers via electrical signals

Q1 Materials Science
Yijun Chen, J. Boyd, M. Naraghi
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引用次数: 0

Abstract

The goal of this research is to establish a highly compact on-demand release platform for functional materials where porous nanofibers serve as the host, heat-based release trigger and temperature controller for regulated release. The ability to store functional materials in fibers and release them on demand via external signals may open up new frontiers in areas such as smart textiles and autonomous composites. The host material was porous carbon nanofibers (CNFs), which encapsulated functional materials, protected by a thin polymeric coating to thermally regulate the release. This platform was used to store Gentian violet (GV), an antibacterial material, and release it with highly controllable rates in aqueous environment. The high porosity of the CNF yarns, both inter- and intra-fiber porosity, resulted in a mass loading of as high as ∼50 wt%. The active release was triggered via passing electrical signals through CNF yarn backbone, thereby heating the coating. The rate of release as a function of temperature was measured. It was concluded that the release mechanism is via thermally augmented and reversible diffusion rates of GV and water through the coating. By applying electric current, the diffusion coefficient of the coating was increased, and the release rate dramatically increased in a reversible fashion by as much as 39×.
导电纳米纤维中功能材料的封装与按需释放
这项研究的目标是为功能材料建立一个高度紧凑的按需释放平台,其中多孔纳米纤维作为主体、基于热量的释放触发器和用于调节释放的温度控制器。将功能材料储存在纤维中并通过外部信号按需释放的能力可能会在智能纺织品和自主复合材料等领域开辟新的前沿。主体材料是多孔碳纳米纤维(CNFs),它封装了功能材料,由薄聚合物涂层保护,以热调节释放。该平台用于储存龙胆紫(GV),一种抗菌材料,并在水环境中以高度可控的速率释放。CNF纱线的高孔隙率,包括纤维间和纤维内的孔隙率,导致高达~50wt%的质量负载。活性释放是通过使电信号通过CNF纱线骨架来触发的,从而加热涂层。测量了作为温度函数的释放速率。得出的结论是,释放机制是通过GV和水通过涂层的热增强和可逆扩散速率。通过施加电流,涂层的扩散系数增加,释放速率以可逆的方式显著增加了39倍。
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
Multifunctional Materials
Multifunctional Materials Materials Science-Materials Science (miscellaneous)
CiteScore
12.80
自引率
0.00%
发文量
9
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