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Flotation separation of hazardous polyvinyl chloride towards source control of microplastics based on selective hydrophilization of plasticizer-doping surfaces
Journal of Hazardous Materials2021
28 citations
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Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count.
Score: 40
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0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Yingshuang Zhang,
Yingshuang Zhang,
Yingshuang Zhang,
Yingshuang Zhang,
Yingshuang Zhang,
Yingshuang Zhang,
Hui Wang,
Hongru Jiang,
Hongru Jiang,
Chongqing Wang
Chongqing Wang
Hongru Jiang,
Hongru Jiang,
Chongqing Wang
Hongru Jiang,
Hongru Jiang,
Hui Wang,
Hongru Jiang,
Hongru Jiang,
Chongqing Wang
Chongqing Wang
Kai Bian,
Hongru Jiang,
Hongru Jiang,
Hongru Jiang,
Hongru Jiang,
Hongru Jiang,
Hongru Jiang,
Chongqing Wang
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Yingshuang Zhang,
Yingshuang Zhang,
Yingshuang Zhang,
Yingshuang Zhang,
Yingshuang Zhang,
Yingshuang Zhang,
Yingshuang Zhang,
Hui Wang,
Chongqing Wang
Hongru Jiang,
Yingshuang Zhang,
Chongqing Wang
Kai Bian,
Kai Bian,
Hui Wang,
Yingshuang Zhang,
Hongru Jiang,
Kai Bian,
Hui Wang,
Hui Wang,
Kai Bian,
Kai Bian,
Kai Bian,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Chongqing Wang
Hui Wang,
Yingshuang Zhang,
Kai Bian,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Kai Bian,
Yingshuang Zhang,
Yingshuang Zhang,
Hongru Jiang,
Hui Wang,
Chongqing Wang
Hui Wang,
Chongqing Wang
Chongqing Wang
Chongqing Wang
Chongqing Wang
Chongqing Wang
Chongqing Wang
Hongru Jiang,
Hui Wang,
Hui Wang,
Chongqing Wang
Hui Wang,
Chongqing Wang
Chongqing Wang
Hui Wang,
Hui Wang,
Chongqing Wang
Hui Wang,
Hui Wang,
Chongqing Wang
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Hui Wang,
Chongqing Wang
Chongqing Wang
Chongqing Wang
Hui Wang,
Hui Wang,
Chongqing Wang
Hongru Jiang,
Hongru Jiang,
Hongru Jiang,
Chongqing Wang
Hui Wang,
Chongqing Wang
Chongqing Wang
Hui Wang,
Hui Wang,
Hongru Jiang,
Yingshuang Zhang,
Chongqing Wang
Chongqing Wang
Chongqing Wang
Hui Wang,
Chongqing Wang
Hongru Jiang,
Chongqing Wang
Chongqing Wang
Summary
Researchers developed a flotation separation method using selective ferric ion deposition to distinguish rigid from flexible PVC plastics based on differences in surface hydrophilicity caused by plasticizer migration, enabling more effective recycling and source control of PVC-derived microplastics.
As the single largest chlorine source of plastics, hazardous polyvinyl chloride (PVC) has become an increasing environmental concern with the rapid microplastics accumulation. An advanced separation method is advocated to purify waste PVC plastics, optimize physical recycling, and protect aquatic and terrestrial environment safety. In this study, we proposed a novel scheme for the flotation separation of PVC plastics with diverse plasticizer contents (PVCs) via regulating hydrophilicity based on a selective ferric deposition. Rigid PVCs were prone to loading ferric ions and generating hydrophilic shells than flexible PVCs. Plasticizers can diffuse freely through the interior and surface of PVC plastics. Abundant plasticizers thereby overlaid the surface of flexible PVC and shielded PVC matrix from ferric ions. By regulating the ferric concentration, the wettability of PVCs was adjusted to separate rigid and flexible PVCs by froth flotation. Waste PVCs could also be separated from each other through the compound process of ferric deposition and flotation, further confirming its feasibility and stability. Thus far, this study supplies distinctive insights into the wettability regulation of plasticizer-doping PVC surfaces, contributes a pioneering hydrophilization method to PVCs separation and recycling, and mitigates hazardous PVC microplastics by source control.