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Constructed wetland, an eco-technology for wastewater treatment: A review on various aspects of microbial fuel cell integration, low temperature strategies and life cycle impact of the technology

Journal

RENEWABLE & SUSTAINABLE ENERGY REVIEWS
Volume 148, Issue -, Pages -

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.rser.2021.111261

Keywords

Microbial fuel cell; LCA; Macrophyte; Cold temperature; Wetlands; Wastewater

Funding

  1. DRDO fellowship

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Constructed wetland technology, as a robust eco-technology for wastewater reclamation, plays a significant role in water security, energy harvesting, and environmental services. Coupling with microbial fuel cell can enhance treatment efficiency and bioelectricity production, but further research and optimization are needed for its profitable futuristic application.
Constructed wetland (CW), a robust eco-technology used for wastewater reclamation can be considered as an ideal synergism among water security, energy harvesting and environmental services. The technology as an alternative to existing energy and chemical intensive treatments has attained maturity for treating contaminants from range of waste streams, under wide range of climates and conditions. Recent trend shows additional research interventions for better expansion of the technology such as energy harvesting to make the system a net energy producer by coupling CW to microbial fuel cell (CW-MFC) and improved operation under climatically challenged condition. The assessment discusses treatment efficiency, bioelectricity production, improved electrode efficiency, performance variation w.r.t. Macrophyte, emerging pollutant removal and microbial community structure in CW-MFC, which reveal that carefully designed integrated CW-MFC with optimized system elements (electrode, spacing, separator, macrophyte, C source, rhizosphere microbes) are necessary for its more profitable futuristic application. Further, low temperature challenges of the technology and the strategies to achieve satisfactory low temperature performance were assessed. Successful implementation of the technology in cold climate calls for design of CW with incorporation of appropriate heat preservation method, active macrophyte or microbial consortia to work effectively under low temperature. Comparative evaluation of the technology with other treatment processes using Life cycle assessment (LCA) with cradle to grave approach (considering alternative substrates, energy harvesting, macrophyte use and disposal options) would further boost the technology penetration. Potential research areas that appear to be worth pursuing in future to obtain further gains in CW performance are also discussed.

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