Sun Wen, Thummavichai Kunyapat, Chen Ding, Lei Yongxin, Pan Hui, Song Taize, Wang Nannan, Zhu Yanqiu
Guangxi Institute Fullerene Technology (GIFT), Key Laboratory of New Processing Technology for Nonferrous Metals and Materials, Ministry of Education, School of Resources, Environment and Materials, Guangxi University, Nanning 530004, China.
Polymers (Basel). 2021 Feb 27;13(5):739. doi: 10.3390/polym13050739.
An efficient, green and reusable catalyst for organic pollutant wastewater treatment has been a subject of intense research in recent decades due to the limitation of current technologies. Cellulose based aerogel composites are considered to be an especially promising candidate for next-generation catalytic material. This project was conducted in order to evaluate the behavior and ability of green and reusable sugarcane bagasse aerogels to remove P-Nitrophesnol from waste-water aqueous. Co-Zeolitic imidazolate framework@ sugarcane bagasse aerogels composite catalysts were successfully prepared via simple in situ synthesis. The structure of hybrid aerogels and their efficient catalyst in peroxymonosulfate (PMS) activation for the degradation of p-nitrophenol (PNP) was investigated. As a result, the hybrid aerogels/PMS system removed 98.5% of PNP (10mg/L) within 60~70 min, while the traditional water treatment technology could not achieve this. In addition, through a free radical capture experiment and electron paramagnetic resonance (EPR), the degradation mechanism of PNP was investigated. Further research found that the hybrid aerogels can effectively activate PMS to produce sulfate (SO) and hydroxyl (OH ). Both of them contributed to the degradation of PNP, and SO plays a crucial role in the degradative process. The most important feature of hybrid aerogels can be easily separated from the solution. The obtained results showed that the outer coating structure of cellulose can stabilize Co-ZIF and reduce the dissolution of cobalt ions under complex reaction conditions. Moreover, the prepared hybrid aerogels exhibit excellent reusability and are environmentally friendly with efficient catalytic efficiency. This work provides a new strategy for bagasse applications and material reusability.
由于现有技术的局限性,近几十年来,一种用于有机污染物废水处理的高效、绿色且可重复使用的催化剂一直是深入研究的课题。基于纤维素的气凝胶复合材料被认为是下一代催化材料特别有前景的候选材料。开展本项目是为了评估绿色且可重复使用的甘蔗渣气凝胶从废水中去除对硝基苯酚的性能和能力。通过简单的原位合成成功制备了钴 - 沸石咪唑酯骨架@甘蔗渣气凝胶复合催化剂。研究了杂化气凝胶的结构及其在过一硫酸盐(PMS)活化降解对硝基苯酚(PNP)方面的高效催化性能。结果表明,杂化气凝胶/PMS体系在60至70分钟内去除了98.5%的PNP(10mg/L),而传统水处理技术无法达到这一效果。此外,通过自由基捕获实验和电子顺磁共振(EPR)研究了PNP的降解机理。进一步研究发现,杂化气凝胶能有效活化PMS产生硫酸根(SO)和羟基(OH)。它们都有助于PNP的降解,且SO在降解过程中起关键作用。杂化气凝胶最重要的特点是能很容易地从溶液中分离出来。所得结果表明,纤维素的外层包覆结构可稳定钴 - 沸石咪唑酯骨架并减少钴离子在复杂反应条件下的溶解。此外,制备的杂化气凝胶具有出色的可重复使用性且环境友好,催化效率高。这项工作为甘蔗渣的应用和材料的可重复使用性提供了一种新策略。
