Multi-Functional Cotton Fabrics with Self-Assembled TiO2 Nanoparticle Seed/TiO2 Nanorod/ZnO Nanoparticle/ Stearic Acid Nanotechnological Architectures

Rajapakshe Rbsd, Thennakoon Ca, Zajid Ama, Rajapakse Rmg, S. Rajapakse
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引用次数: 1

Abstract

With the intricate day-to-day lives of the modern people, simple and time-efficient accessories are always needed to make their daily routine more convenient and comfortable. When it comes to the garment materials, it would be particularly important to have low energy and less time consuming ways to turn them cleaner. Herein, this work has introduced a novel method to manufacture multi-functional textiles, possessing antimicrobial, self-cleaning and super-hydrophobic properties via a nano-technological approach. Titanium dioxide nano-rods and Zinc oxide nanoparticles together with self-assembled stearic acid molecules had been used as the nano-technological components to give these multi-functional properties for cotton fabric. The method was very simple and low cost, which makes it up-scalable and reliable in the industrial avenue. In order to characterize those nanomaterials, X-Ray diffractometry, X-Ray Fluoresce, Scanning Electron microscopy, UVVisible spectroscopy and FT-IR methods were used. Conventional microbiological methods were used to investigate their antimicrobial properties. Escherichia coli and Staphylococcus aureus were used to test the antimicrobial property as they represent, respectively, Gram-negative and Gram-positive Bacteria. The water contact angles were measured with optical imaging to determine the super-hydrophobicity. As a photo-catalyst, TiO2 nano-structures has an excellent ability to digest many organic substances by making reactive oxygen species produced by excited electrons in the conduction band and through highly oxidizing holes remaining in the valence band. ZnO nanoparticles also act in a similar manner through photo-catalysis and kill the microbial cells by destroying the organic components in the cell membrane. The protrude-like structures of these modified ZnO nano-structures can penetrate the bacterial cells and destroy them even in the dark. Likewise, the entire system made a better platform to turn a regular textile material into a super-hydrophobic, self-cleaning and anti-microbial fabric with a simple modification. As such, these textiles were capable of performing multiple functions due to this surface modification without losing its typical properties such as comfort for wear and hand feel.
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具有自组装TiO2纳米粒子种子/TiO2纳米棒/ZnO纳米粒子/硬脂酸纳米结构的多功能棉织物
现代人的日常生活纷繁复杂,总是需要简单省时的配饰,让日常生活更加方便舒适。在服装材料方面,找到低能耗、低耗时的清洁方法尤为重要。本文介绍了一种利用纳米技术制备具有抗菌、自清洁和超疏水性能的多功能纺织品的新方法。将二氧化钛纳米棒和氧化锌纳米颗粒与自组装硬脂酸分子一起作为纳米技术组分,赋予棉织物这些多功能性能。该方法简单、成本低,可扩展性强,在工业领域应用可靠。为了对这些纳米材料进行表征,采用了x射线衍射、x射线荧光、扫描电镜、紫外可见光谱和傅里叶变换红外光谱等方法。采用常规微生物学方法对其抗菌性能进行了研究。由于大肠杆菌和金黄色葡萄球菌分别代表革兰氏阴性菌和革兰氏阳性菌,因此对其抗菌性能进行了测试。用光学成像法测定了水接触角,确定了超疏水性。作为光催化剂,TiO2纳米结构通过在导带中激发电子和在价带中残留的高氧化空穴产生活性氧来消化许多有机物质,具有优异的能力。ZnO纳米颗粒也以类似的方式通过光催化作用,通过破坏细胞膜中的有机成分来杀死微生物细胞。这些修饰ZnO纳米结构的突起状结构即使在黑暗中也能穿透细菌细胞并破坏它们。同样,整个系统提供了一个更好的平台,通过简单的修改,将普通的纺织材料变成超疏水、自清洁和抗菌的织物。因此,由于这种表面改性,这些纺织品能够执行多种功能,而不会失去其典型的性能,如穿着舒适和手感。
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