CHAPTER 5. Lotus Effect-based Superhydrophobic Surfaces: Candle Soot as a Promising Class of Nanoparticles for Self-cleaning and Oil–Water Separation Applications

S. S. Latthe, K. Nakata, R. Höfer, A. Fujishima, C. Terashima
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引用次数: 13

Abstract

Candle soot consists of hydrophobic carbon nanoparticles (diameter ∼40 ± 10 nm) that can be chiefly collected from the candle flame. There is no other easier and cheaper way available to produce hydrophobic nanoparticles. The deposition of candle soot on any solid surface appears as a black layer with superhydrophobicity, however this layer is delicate and washed away with rolling water drops or by gentle finger touching. The sole use of hydrophobic candle soot nanoparticles could not achieve a durable as well as transparent coating. The candle soot is then used as a template as well as in combination with silica or polymers to achieve durable and transparent superhydrophobic coatings. Candle soot can prove to be an adequate precursor in the preparation of superhydrophobic coatings and oil–water separation sponges/meshes due to its easy availability for everyone. The researchers who are eager to jump into superhydrophobic surface research with a low level of funding can start with candle soot. Novel ideas and techniques should be adopted to fabricate candle soot based superhydrophobic surfaces. The use of candle soot nanoparticles in industrial products can reduce the price of the final product reasonably.
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第五章。基于莲花效应的超疏水表面:蜡烛烟灰作为一种有前途的自清洁和油水分离应用的纳米颗粒
蜡烛烟灰由疏水碳纳米颗粒(直径~ 40±10 nm)组成,主要可以从蜡烛火焰中收集。没有其他更容易、更便宜的方法来生产疏水纳米粒子。蜡烛烟灰的沉积在任何固体表面上都表现为一层黑色的超疏水性,然而这层是脆弱的,可以用滚动的水滴或温柔的手指触摸洗掉。单一使用疏水性蜡烛烟灰纳米粒子无法获得耐用和透明的涂层。然后将蜡烛烟灰用作模板,并与二氧化硅或聚合物结合使用,以获得耐用和透明的超疏水涂层。蜡烛烟灰可以证明是制备超疏水涂层和油水分离海绵/网的适当前体,因为它易于获得。那些渴望以较低的资金投入超疏水表面研究的研究人员可以从蜡烛烟灰开始。蜡烛烟灰基超疏水表面的制备应采用新颖的思路和技术。在工业产品中使用蜡烛烟灰纳米颗粒可以合理降低最终产品的价格。
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Chapter 7. Integrating Remediation and Resource Recovery of Industrial Alkaline Wastes: Case Studies of Steel and Alumina Industry Residues Chapter 8. Conclusions Chapter 11. Applications of Engineered Nanomaterials in the Recovery of Metals from Wastewater Chapter 6. An Exploration of Key Concepts in Application of In Situ Processes for Recovery of Resources from High-volume Industrial and Mine Wastes Chapter 5. Adding Value to Ash and Digestate (AVAnD Project): Elucidating the Role and Value of Alternative Fertilisers on the Soil–Plant System
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