THE EFFECT OF ESSENTIAL OIL ON FIBER MORPHOLOGY AND SURFACE PROPERTIES IN COAXIAL NANOFIBERS

Uludağ University Journal of The Faculty of Engineering Pub Date : 2024-02-15 DOI:10.17482/uumfd.1359257

Nursema Pala Avcı, Nebahat Aral Yılmaz, F. Nergis

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Abstract

In this study, core-shell nanofibers were produced by using hydrophilic polyvinylpyrrolidone (PVP) polymer in the core and hydrophobic poly(e-caprolactone) (PCL) polymer in the shell. Essential oil added nanofiber structures were developed by adding thyme oil (TEO) and borage oil (BO) in the PVP core part by using Triton X 100 (TX-100) as the surfactant. 8% PVP-8% PCL nanofibers were produced by adding TEO, BO and a 1:1 volume/volume mixture of these two (TEO:BO) to the PVP solution. Addition of essential oil and surfactant to the solutions resulted in different conductivity and viscosity values. SEM images were analyzed and it was observed that nanofiber diameters increased when essential oil and surfactant were added to the core of the coaxial nanofibers. Pristine, TEO-added, TEO:BO added and BO-added nanofibers were calculated as 145 ± 66, 233 ± 150, 245 ± 165 and 300 ± 124 nm, respectively. Besides, water contact angle measurements showed that TX-100 and essential oil additives caused high hydrophilization of nanofiber by changing the hydrophobic nature of PCL. While the contact angle of the 8% PVP-8% PCL sample without additives were 98°, the contact angle of the oil and surfactant containing samples were measured as 0°. In conclusion, it was observed that the nanofiber morphology and surface properties changed when different essential oils and surfactant were added to the core-shell nanofibers.

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精油对同轴纳米纤维形态和表面特性的影响

本研究以亲水性聚乙烯吡咯烷酮（PVP）聚合物为芯，疏水性聚己内酯（PCL）聚合物为壳，制备了芯壳纳米纤维。通过使用 Triton X 100（TX-100）作为表面活性剂，在 PVP 核心部分添加百里香油（TEO）和琉璃苣油（BO），开发出了添加精油的纳米纤维结构。在 PVP 溶液中加入 TEO、BO 以及这两种物质体积/体积比为 1:1 的混合物（TEO:BO），可制成 8% PVP-8% PCL 纳米纤维。在溶液中加入精油和表面活性剂会产生不同的电导率和粘度值。通过分析扫描电子显微镜图像可以发现，当在同轴纳米纤维的核心中添加精油和表面活性剂时，纳米纤维的直径会增大。经计算，原始纳米纤维、添加 TEO 的纳米纤维、添加 TEO:BO 的纳米纤维和添加 BO 的纳米纤维的直径分别为 145 ± 66 nm、233 ± 150 nm、245 ± 165 nm 和 300 ± 124 nm。此外，水接触角测量结果表明，TX-100 和精油添加剂通过改变 PCL 的疏水性，使纳米纤维具有较高的亲水性。不含添加剂的 8% PVP-8% PCL 样品的接触角为 98°，而含油和表面活性剂的样品的接触角则为 0°。总之，在芯壳纳米纤维中添加不同的精油和表面活性剂后，纳米纤维的形态和表面特性都发生了变化。

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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Uludağ University Journal of The Faculty of Engineering

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