Frontiers of Chemical Science and Engineering >
Removal of dyes from wastewater by growing fungal pellets in a semi-continuous mode
Received date: 19 Nov 2016
Accepted date: 09 Feb 2017
Published date: 23 Aug 2017
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To increase the efficiency of dye removal from wastewater using mycelial pellets, a bubble column reactor with a simple structure was designed and efficiently used to remove dyes from solution containing dyes. The mycelial pellets were prepared by marine fungus Aspergillus niger ZJUBE-1. Eight dyes were tested as dye targets for the adsorption capacity of mycelial pellets and good removal results were obtained. Eriochrome black T was selected as a model dye for characterizing the adsorption processes in detail. The measurement results of Zeta potential and FT-IR analysis indicate that the electrostatic attraction may play a key role in the biosorption process. The bubble column reactor was utilized to study the batch dye-removal efficiency of mycelial pellets. A re-culture process between every two batches, which was under non-sterile condition, successfully enhanced the utilization of mycelium biomass. The dye removal rate is 96.4% after 12 h in the first batch and then decreases slowly in the following batches. This semi-continuous mode, which consists of commutative processes of dye-removal and re-culture, has some outstanding advantages, such as low power consumption, easy operation, high dye removal rate, and efficient biomass utilization.
Tao Lu , Qilei Zhang , Shanjing Yao . Removal of dyes from wastewater by growing fungal pellets in a semi-continuous mode[J]. Frontiers of Chemical Science and Engineering, 2017 , 11(3) : 338 -345 . DOI: 10.1007/s11705-017-1644-0
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