Titlebook: Development of Novel Bioelectrochemical Membrane Separation Technologies for Wastewater Treatment an; Yunkun Wang Book 2020 Springer Natur

Deject

Introduction, leaded to the current energy and resource crisis, and also caused adverse effects on the environment. Water pollution and the resulting shortage of water resources also seriously threaten human health and social development.

音的強(qiáng)弱

節(jié)約

Development of Electrochemical Membrane Bioreactor Technologies for Sustainable Wastewater Treatmen In addition, high-quality clean water was obtained for reuse. The results clearly demonstrate that, under the optimized operating conditions, it is possible to recover net energy from wastewater, while at the same time to harvest high-quality effluent for reuse with this novel wastewater treatment system.

珍奇

Mitochondriale DNA des Menschen 45:7100–7106, 2011 [.]; Vorosmarty et al. in Nature 467:555–561, 2010 [.]). The over-exploitation and irrational use of resources by human beings has leaded to the current energy and resource crisis, and also caused adverse effects on the environment. Water pollution and the resulting shortage of w

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蟄伏

conformity

https://doi.org/10.1007/978-3-322-94877-9stewater. Herein, novel electrochemical membrane bioreactors EMBRs, which take advantage of a membrane bioreactor and microbial fuel cells, were developed to recover energy from wastewater and meantime harvest clean water for reuse. With the help of the microorganisms in the biocatalysis and biodegr

狂熱語(yǔ)言

https://doi.org/10.1007/978-3-322-94877-9al membrane bioreactor (EMBR) was developed based on in situ utilization of the generated electricity for fouling control. In this system, a maximum power density of 1.43?W/m. and a current density of 18.49?A/m. were obtained. The results demonstrate that the formed electric field reduced the deposi

organic-matrix

syring