PDF
(371KB)
Abstract
• Energy is needed to accelerate the biological wastewater treatment.
• Electrical energy input in traditional technology is indirect and inefficient.
• Direct injection of electricity can be a game changer to maximize energy efficiency.
• Microbial electrochemical unit for decentralized wastewater treatment is proposed.
It has been more than one century since the activated sludge process was invented. Despite its proven stability and reliability, the energy (especially the electrical energy) use in wastewater treatment should evolve to meet the increasingly urgent demand of energy efficiency. This paper discusses how the energy utilized in conventional biological wastewater treatment can be altered by switching the indirect energy input to a direct electricity injection, which is achieved by the electrode integration providing extra thermodynamic driving force to biodegradation. By using electrodes instead of oxygen as terminal electron acceptors, the electrical energy can be utilized more efficiently, and the key of direct use of electrical energy in biodegradation is the development of highly active electroactive biofilm and the increase of electron transfer between microbes and the electrode. Furthermore, the synergy of different microbial electrochemical units has additional benefit in energy and resource recovery, making wastewater treatment more sustainable.
Graphical abstract
Keywords
Biological wastewater treatment
/
Integrated energy view
/
Electroactive bacteria
/
Extracellular electron transfer
Cite this article
Download citation ▾
Yuqing Yan, Xin Wang.
Integrated energy view of wastewater treatment: A potential of electrochemical biodegradation.
Front. Environ. Sci. Eng., 2022, 16(4): 52 DOI:10.1007/s11783-021-1486-3
| [1] |
Chen X, Gao Y, Hou D, Ma H, Lu L, Sun D, Zhang X, Liang P, Huang X, Ren J Z (2017). The microbial electrochemical current accelerates urea hydrolysis for recovery of nutrients from source-separated urine. Environmental Science & Technology Letters, 4(7): 305–310
|
| [2] |
Li N, Wan Y, Wang X (2020). Nutrient conversion and recovery from wastewater using electroactive bacteria. Science of the Total Environment, 706: 135690
|
| [3] |
Li W W, Yu H Q, Rittmann B E (2015). Chemistry: Reuse water pollutants. Nature, 528(7580): 29–31
|
| [4] |
Logan B E, Rabaey K (2012). Conversion of wastes into bioelectricity and chemicals by using microbial electrochemical technologies. Science, 337(6095): 686–690
|
| [5] |
McCarty P L, Bae J, Kim J (2011). Domestic wastewater treatment as a net energy producer--can this be achieved? Environmental Science & Technology, 45(17): 7100–7106
|
| [6] |
Ren Z J, Umble A K (2016). Recover wastewater resources locally. Nature, 529(7584): 25
|
| [7] |
Rittmann B E, McCarty P L (2001). Environmental Biotechnology: Principles and Applications. New York: McGraw-Hill Book Co.
|
| [8] |
Shi L, Dong H, Reguera G, Beyenal H, Lu A, Liu J, Yu H Q, Fredrickson J K (2016). Extracellular electron transfer mechanisms between microorganisms and minerals. Nature Reviews Microbiology, 14(10): 651–662 PMID:27573579
|
| [9] |
van Loosdrecht M C M, Brdjanovic D (2014). Anticipating the next century of wastewater treatment. Science, 344(6191): 1452–1453
|
| [10] |
Walker D J F, Nevin K P, Holmes D E, Rotaru A E, Ward J E, Woodard T L, Zhu J, Ueki T, Nonnenmann S S, McInerney M J, Lovley D R (2020). Syntrophus conductive pili demonstrate that common hydrogen-donating syntrophs can have a direct electron transfer option. The ISME Journal, 14(3): 837–846
|
| [11] |
Wilson E L, Kim Y (2016). The yield and decay coefficients of exoelectrogenic bacteria in bioelectrochemical systems. Water Research, 94: 233–239
|
| [12] |
Yan X, Lee H S, Li N, Wang X (2020). The micro-niche of exoelectrogens influences bioelectricity generation in bioelectrochemical systems. Renewable & Sustainable Energy Reviews, 134: 110184
|
| [13] |
Yan Y, Wang X (2019). Ecological responses to substrates in electroactive biofilm: A review. Science China Technological Sciences, 62(10): 1657–1669
|
| [14] |
Zhao Q, An J, Wang X, Li N (2021). In-situ hydrogen peroxide synthesis with environmental applications in bioelectrochemical systems: A state-of-the-art review. International Journal of Hydrogen Energy, 46(4): 3204–3219
|
RIGHTS & PERMISSIONS
Higher Education Press
