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Using a sulfur autotrophic fluidized bed reactor for simultaneous perchlorate and nitrate removal from water: S disproportionation prediction and system optimization
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  • Yongde Liu,
  • Yang Liu,
  • Qiaochong He,
  • Qi Li,
  • Dongjin Wan,
  • Jia Zhou
Yongde Liu
Henan University of Technology

Corresponding Author:liuyongde@haut.edu.cn

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Yang Liu
Henan University of Technology
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Qiaochong He
Henan University of Technology
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Qi Li
Henan University of Technology
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Dongjin Wan
Henan University of Technology
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Jia Zhou
Henan University of Technology
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Abstract

A sulfur autotrophic fluidized bed reactor was established to overcome mass transfer problems and shorten the co-reduction time for perchlorate and nitrate from aqueous solution. Response surface methodology (RSM) was used to predict the subsequent extent of sulfur (S) disproportionation based on three variable parameters, namely the hydraulic retention time (HRT), co-existing nitrate concentration (C_〖inf 〗⁡〖〖NO〗_3^–N〗 ) and recirculation ratio (R). The extent of sulfur (S) disproportionation was determined by sulfate generation and alkalinity consumption. RSM results show that a long HRT and high R promoted whereas co-existing nitrate inhibited sulfate production from S disproportionation. For complete perchlorate and nitrate reduction (>98.45%) with relatively low sulfate generation (236.07 mg/L), the optimal HRT, C_〖inf 〗⁡〖〖NO〗_3^–N〗 and R were 0.50 h, 10 mg/L and 14, respectively. High-throughput sequencing revealed that Chlorobaculum was associated with S disproportionation while the abundance of Sulfurovum, an effective denitrification/perchlorate reducing bacteria, decreased over the height of the reactor.
08 Oct 2020Submitted to Biotechnology and Bioengineering
08 Oct 2020Submission Checks Completed
08 Oct 2020Assigned to Editor
27 Jul 2021Published in Biodegradation. 10.1007/s10532-021-09957-8