Simultaneous water desalination and electricity generation in a microbial desalination cell with electrolyte recirculation for pH control

Youpeng Qu; Yujie Feng; Xin Wang; Jia Liu; Jiangwei Lv; Weihua He; Bruce E. Logan

doi:10.1016/j.biortech.2011.11.045

Simultaneous water desalination and electricity generation in a microbial desalination cell with electrolyte recirculation for pH control

Youpeng Qu
, Yujie Feng^*
, Xin Wang
, Jia Liu
, Jiangwei Lv
, Weihua He
, Bruce E. Logan

^*Corresponding author for this work

School of Environment

Research output: Contribution to journal › Article › peer-review

181 Scopus citations

Abstract

A recirculation microbial desalination cell (rMDC) was designed and operated to allow recirculation of solutions between the anode and cathode chambers. This recirculation avoided pH imbalances that could inhibit bacterial metabolism. The maximum power density was 931±29mW/m ² with a 50mM phosphate buffer solution (PBS) and 776±30mW/m ² with 25mM PBS. These power densities were higher than those obtained without recirculation of 698±10mW/m ² (50mM PBS) and 508±11mW/m ² (25mM PBS). The salt solution (20g/L NaCl) was reduced in salinity by 34±1% (50mM) and 37±2% (25mM) with recirculation (rMDC), and by 39±1% (50mM) and 25±3% (25mM) without recirculation (MDC). These results show that electrolyte recirculation using an rMDC is an effective method to increase power and achieve efficient desalination by eliminating pH imbalances.

Original language	English
Pages (from-to)	89-94
Number of pages	6
Journal	Bioresource Technology
Volume	106
DOIs	https://doi.org/10.1016/j.biortech.2011.11.045
State	Published - Feb 2012

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

Microbial desalination cell
PH imbalance
Recirculation

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10.1016/j.biortech.2011.11.045

Cite this

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title = "Simultaneous water desalination and electricity generation in a microbial desalination cell with electrolyte recirculation for pH control",

abstract = "A recirculation microbial desalination cell (rMDC) was designed and operated to allow recirculation of solutions between the anode and cathode chambers. This recirculation avoided pH imbalances that could inhibit bacterial metabolism. The maximum power density was 931±29mW/m 2 with a 50mM phosphate buffer solution (PBS) and 776±30mW/m 2 with 25mM PBS. These power densities were higher than those obtained without recirculation of 698±10mW/m 2 (50mM PBS) and 508±11mW/m 2 (25mM PBS). The salt solution (20g/L NaCl) was reduced in salinity by 34±1\% (50mM) and 37±2\% (25mM) with recirculation (rMDC), and by 39±1\% (50mM) and 25±3\% (25mM) without recirculation (MDC). These results show that electrolyte recirculation using an rMDC is an effective method to increase power and achieve efficient desalination by eliminating pH imbalances.",

keywords = "Microbial desalination cell, PH imbalance, Recirculation",

author = "Youpeng Qu and Yujie Feng and Xin Wang and Jia Liu and Jiangwei Lv and Weihua He and Logan, \{Bruce E.\}",

year = "2012",

month = feb,

doi = "10.1016/j.biortech.2011.11.045",

language = "英语",

volume = "106",

pages = "89--94",

journal = "Bioresource Technology",

issn = "0960-8524",

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TY - JOUR

T1 - Simultaneous water desalination and electricity generation in a microbial desalination cell with electrolyte recirculation for pH control

AU - Qu, Youpeng

AU - Feng, Yujie

AU - Wang, Xin

AU - Liu, Jia

AU - Lv, Jiangwei

AU - He, Weihua

AU - Logan, Bruce E.

PY - 2012/2

Y1 - 2012/2

N2 - A recirculation microbial desalination cell (rMDC) was designed and operated to allow recirculation of solutions between the anode and cathode chambers. This recirculation avoided pH imbalances that could inhibit bacterial metabolism. The maximum power density was 931±29mW/m 2 with a 50mM phosphate buffer solution (PBS) and 776±30mW/m 2 with 25mM PBS. These power densities were higher than those obtained without recirculation of 698±10mW/m 2 (50mM PBS) and 508±11mW/m 2 (25mM PBS). The salt solution (20g/L NaCl) was reduced in salinity by 34±1% (50mM) and 37±2% (25mM) with recirculation (rMDC), and by 39±1% (50mM) and 25±3% (25mM) without recirculation (MDC). These results show that electrolyte recirculation using an rMDC is an effective method to increase power and achieve efficient desalination by eliminating pH imbalances.

AB - A recirculation microbial desalination cell (rMDC) was designed and operated to allow recirculation of solutions between the anode and cathode chambers. This recirculation avoided pH imbalances that could inhibit bacterial metabolism. The maximum power density was 931±29mW/m 2 with a 50mM phosphate buffer solution (PBS) and 776±30mW/m 2 with 25mM PBS. These power densities were higher than those obtained without recirculation of 698±10mW/m 2 (50mM PBS) and 508±11mW/m 2 (25mM PBS). The salt solution (20g/L NaCl) was reduced in salinity by 34±1% (50mM) and 37±2% (25mM) with recirculation (rMDC), and by 39±1% (50mM) and 25±3% (25mM) without recirculation (MDC). These results show that electrolyte recirculation using an rMDC is an effective method to increase power and achieve efficient desalination by eliminating pH imbalances.

KW - Microbial desalination cell

KW - PH imbalance

KW - Recirculation

UR - https://www.scopus.com/pages/publications/84855345089

U2 - 10.1016/j.biortech.2011.11.045

DO - 10.1016/j.biortech.2011.11.045

M3 - 文章

C2 - 22200556

AN - SCOPUS:84855345089

SN - 0960-8524

VL - 106

SP - 89

EP - 94

JO - Bioresource Technology

JF - Bioresource Technology

ER -

Simultaneous water desalination and electricity generation in a microbial desalination cell with electrolyte recirculation for pH control

Abstract

UN SDGs

Keywords

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