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Development of novel bioelectrochemical membrane separation technologies for wastewater treatment and resource recovery

Record Type:	Electronic resources : Monograph/item
Title/Author:	Development of novel bioelectrochemical membrane separation technologies for wastewater treatment and resource recoveryby Yunkun Wang.
Author:	Wang, Yunkun.
Published:	Singapore :Springer Singapore :2020.
Description:	xiv, 157 p. :ill., digital ;24 cm.
Contained By:	Springer eBooks
Subject:	SewagePurification
Online resource:	https://doi.org/10.1007/978-981-15-3078-4
ISBN:	9789811530784$q(electronic bk.)

Development of novel bioelectrochemical membrane separation technologies for wastewater treatment and resource recovery
Wang, Yunkun.

Development of novel bioelectrochemical membrane separation technologies for wastewater treatment and resource recovery[electronic resource] /by Yunkun Wang. - Singapore :Springer Singapore :2020. - xiv, 157 p. :ill., digital ;24 cm. - Springer theses,2190-5053. - Springer theses..

Introduction -- Research background -- Intermittently aerated membrane bioreactor technologies for nutrients removal and phosphate recovery -- Anaerobic hybrid membrane bioreactor technology for refractory organic pollutant removal -- Electrochemical membrane bioreactor technologies for sustainable wastewater treatment -- In-situ utilization of generated electricity to mitigate membrane fouling -- In-situ utilization of generated electricity for nutrient recovery -- Conclusion -- acknowledgement -- Academic papers and patents during doctoral studies.

The most commonly used biological wastewater treatment technologies still have serious technical-economical and sustainability-related limitations, due to their high energy requirements, poor effluent quality, and lack of energy and resource recovery processes. In this thesis, novel electrochemical membrane bioreactors (EMBRs), which take advantage of membrane separation and bioelectrochemical techniques, are developed for wastewater treatment and the simultaneous recovery of energy and resources. Above all, this innovative system holds great promise for the eﬃcient wastewater treatment and energy recovery. It can potentially recover net energy from wastewater while at the same time harvesting high-quality effluent. The book also provides a proof-of-concept study showing that electrochemical control might offer a promising in-situ means of suppressing membrane fouling. Lastly, by integrating electrodialysis into EMBRs, phosphate separation and recovery are achieved. Hence, these new EMBR techniques provide viable alternatives for sustainable wastewater treatment and resource recovery.

ISBN: 9789811530784$q(electronic bk.)

Standard No.: 10.1007/978-981-15-3078-4doiSubjects--Topical Terms:

196743
Sewage
--Purification

LC Class. No.: TD755 / .W364 2020

Dewey Class. No.: 628.35

Development of novel bioelectrochemical membrane separation technologies for wastewater treatment and resource recovery
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505 0 $a Introduction -- Research background -- Intermittently aerated membrane bioreactor technologies for nutrients removal and phosphate recovery -- Anaerobic hybrid membrane bioreactor technology for refractory organic pollutant removal -- Electrochemical membrane bioreactor technologies for sustainable wastewater treatment -- In-situ utilization of generated electricity to mitigate membrane fouling -- In-situ utilization of generated electricity for nutrient recovery -- Conclusion -- acknowledgement -- Academic papers and patents during doctoral studies.
520 $a The most commonly used biological wastewater treatment technologies still have serious technical-economical and sustainability-related limitations, due to their high energy requirements, poor effluent quality, and lack of energy and resource recovery processes. In this thesis, novel electrochemical membrane bioreactors (EMBRs), which take advantage of membrane separation and bioelectrochemical techniques, are developed for wastewater treatment and the simultaneous recovery of energy and resources. Above all, this innovative system holds great promise for the eﬃcient wastewater treatment and energy recovery. It can potentially recover net energy from wastewater while at the same time harvesting high-quality effluent. The book also provides a proof-of-concept study showing that electrochemical control might offer a promising in-situ means of suppressing membrane fouling. Lastly, by integrating electrodialysis into EMBRs, phosphate separation and recovery are achieved. Hence, these new EMBR techniques provide viable alternatives for sustainable wastewater treatment and resource recovery.
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