Integrated microbial fuel cells for wastewater treatment [electronic resource] / [edited by] Rouzbeh Abbassi, Asheesh Kumar Yadav, Faisal Khan, Vikram Garaniya.
- 其他作者:
- 出版: Amsterdam : Butterworth-Heinemann 2020.
- 主題: Sewage--Purification--Biological treatment. , Microbial fuel cells. , Microbial fuel cells. , Sewage--Purification--Biological treatment. , Electronic books.
- ISBN: 0128174943 (electronic bk.) 、 9780128174944 (electronic bk.) 、 9780128174937 、 0128174935
- URL:
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- 一般註:Includes index. Front Cover -- Integrated Microbial Fuel Cells for Wastewater Treatment -- Copyright Page -- Contents -- List of contributors -- 1 Introduction -- 1 Introduction to microbial fuel cells: challenges and opportunities -- 1.1 Introduction -- 1.2 Brief history of microbial fuel cells to bioelectrochemical systems -- 1.3 Principles and challenges of microbial fuel cells -- 1.4 Future of microbial fuel cells -- 1.5 Conclusion -- Acknowledgment -- References -- 2 Microbial fuel cell-integrated wastewater treatment systems -- 2.1 Introduction -- 2.1.1 Sediment microbial fuel cells 2.1.2 Constructed wetlands-microbial fuel cells -- 2.1.3 MBR-microbial fuel cells -- 2.1.4 Desalination cell-microbial fuel cells -- 2.1.5 Other processes -- 2.2 Conclusion -- References -- 2 Application to Industrial Wastewater treatment -- 3 Removal of heavy metals using bioelectrochemical systems -- 3.1 Introduction -- 3.2 Bioelectrochemical systems for heavy metal removal -- 3.2.1 Concept and principle -- 3.2.2 Reduction of heavy metals at the cathode of bioelectrochemical systems -- 3.3 Electrode materials used for heavy metal removal in bioelectrochemical systems 3.4 Conventional technologies versus bioelectrochemical systems-based technology for the removal of heavy metals -- 3.5 Conclusion -- References -- Further reading -- 4 Textile wastewater treatment using microbial fuel cell and coupled technology: a green approach for detoxification and bi... -- 4.1 Microbial fuel cell and its application in the treatment -- 4.1.1 Mechanisms involved in dye breakdown -- 4.1.2 Dye removal and current generation in microbial fuel cell -- 4.1.3 Dye removal and total COD removal -- 4.2 Enhancement of microbial fuel cell performance 4.2.1 Bioanode-based enhancement of dye treatment -- 4.2.2 Biocathode-based enhancement of dye treatment -- 4.2.3 Membrane-based enhancement of dye treatment -- 4.2.4 Effect of the shuttle on dye removal and electricity generation -- 4.3 Microbial diversity involved in the breakdown of dye in microbial fuel cell -- 4.4 Toxicity of treated dye wastewater -- 4.5 Microbial fuel cell-coupled techniques for textile wastewater treatment -- 4.5.1 Microbial fuel cell-integrated constructed wetlands -- 4.5.2 Microbial fuel cell couple aerobic biocontact oxidation reactor system 4.5.3 Bioelectro-Fenton technology-microbial fuel cell -- 4.5.4 Electrolysis cell combined with a microbial fuel cell (MFC-MEC) -- 4.6 Research gap -- Acknowledgments -- References -- Further reading -- 5 Agro-industrial wastewater treatment in microbial fuel cells -- 5.1 Introduction -- 5.2 Use of agro-industrial wastewater as substrate for microbial fuel cells -- 5.3 Dairy industry wastewater -- 5.4 Brewery and winery industry -- 5.4.1 Brewery wastewater -- 5.4.2 Winery wastewater -- 5.5 Agro-industrial wastewaters and by-products -- 5.5.1 Palm oil industry wastewater 110年度臺灣學術電子書暨資料庫聯盟採購
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- 系統號: 000291902 | 機讀編目格式
館藏資訊
Current wastewater treatment technologies are not sustainable simply due to their high operational costs and process inefficiency. Integrated Microbial Fuel Cells for Wastewater Treatment is intended for professionals who are searching for an innovative method to improve the efficiencies of wastewater treatment processes by exploiting the potential of Microbial Fuel Cells (MFCs) technology. The book is broadly divided into four sections. It begins with an overview of the "state of the art" bioelectrochemical systems (BESs) as well as the fundamentals of MFC technology and its potential to enhance wastewater treatment efficiencies and reduce electricity generation cost. In section two, discusses the integration, installation, and optimization of MFC into conventional wastewater treatment processes such as activated sludge process, lagoons, constructed wetlands, and membrane bioreactors. Section three outlines integrations of MFCs into other wastewater processes. The final section provides explorative studies of MFC integrated systems for large scale wastewater treatment and the challenges which are inherent in the upscaling process. Clearly describes the latest techniques for integrating MFC into traditional wastewater treatment processes such as activated sludge process, lagoons, constructed wetlands, and membrane bioreactors Discusses the fundamentals of bioelectrochemical systems for degrading the contaminants from the municipal and industrial wastewater Covers methods for the optimization of integrated systems
