Robust and efficient oil-water separation using candle soot deposited stainless steel mesh

In light of the increasingly severe pollution of water bodies by oily wastewater and organic matter, it is crucial to develop oil–water separation membranes with high stability and high flux. By depositing candle soot and polymerized phytic acid on stainless steel mesh, such membranes can be effecti...

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Bibliographic Details
Published in:Separation and purification technology 2025-06, Vol.359, p.130530, Article 130530
Main Authors: Li, Shuo, Xie, Shangzhen, Chen, Guopeng, Zhang, Congji, Xiang, Kang, Guo, Zhiguang
Format: Article
Language:English
Subjects:
Candles soot deposition
Oil-water separation
Stainless steel mesh
Superhydrophilic surface
Superoleophobic membrane
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Summary:In light of the increasingly severe pollution of water bodies by oily wastewater and organic matter, it is crucial to develop oil–water separation membranes with high stability and high flux. By depositing candle soot and polymerized phytic acid on stainless steel mesh, such membranes can be effectively prepared. [Display omitted] In recent years, the rising concerns regarding oil pollution and the emissions of organic pollutants from industrial activities have posed significant environmental and public health challenges. The treatment of oily wastewater and organic pollutants has emerged as pressing issue, necessitating the development of efficient solutions. Oil-water separation stands out as a promising approach to address these challenges. However, the effictiveness and robustness of the separating membranes have been identified as key limitations hindering the advancement of oil–water separation technologiess. This paper introduces a novel superhydrophilic/underwater superoleophobic membrane tailored specifically for oil–water separation with enhanced water flux. This film is prepared by depositing candle soot on a stainless steel mesh and then polymerizing phytic acid (CSM-PA). The contact angle of CSM-PA membranes underwater for a wide range of oils is above 140°, reaching a maximum of 152.73°. The CSM-PA membrane demonstrates excellent separation performance for various oils, achieving separation efficiencies flux surpassing 99.990 %, achieving separation efficiencies flux surpassing 18950.360 L·m−2·h−1. Notably, the membrane exhibits contact angles under water exceeding 142° for all oils tested. After conducting immersion, sand impact, and water impact tests, the underwater contact angle for both light and heavy oils was found to exceed 139°. The surface roughness of the CSM-PA film on the initial stainless steel mesh improved significantly, increasing from 106 nm to 452 nm. Impressively, even after 70 cycles, the CSM-PA membrane maintains an oil (n-hexane) water separation efficiency exceeding 99.997 % and a remarkable flux rate of 21055.956 L·m−2·h−1, the maximum separation flux is even 29154.400 L·m−2·h−1. Furthermore, the CSM-PA membrane shows significant stability and resistance to mechanical abrasion, ensuring long-term and reliable operational performance. The findings of this study hold significant implications for the advancement of oil–water separation technologies, offering a promising avenue for addressing oil pollution and organic pol
ISSN:1383-5866
DOI:10.1016/j.seppur.2024.130530