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The near-future integration of microbial desalination cells with reverse osmosis technology
ElMekawy, A.; Hegab, H.M.; Pant, D. (2014). The near-future integration of microbial desalination cells with reverse osmosis technology. Energy & Environmental Science 7(12): 3921-3933. https://dx.doi.org/10.1039/c4ee02208d
In: Energy & Environmental Science. ROYAL SOC CHEMISTRY: Cambridge. ISSN 1754-5692; e-ISSN 1754-5706, meer
Peer reviewed article  

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  • ElMekawy, A., meer
  • Hegab, H.M.
  • Pant, D., meer

Abstract
    The combined negative effect of both fresh water shortage and energy depletion has encouraged the research to move forward to explore effective solutions for water desalination with less energy consumption. Reverse osmosis (RO), the most common technology for desalination today, uses much less energy than thermal processes. Several modifications and improvements have been made to RO during the last four decades in order to minimize energy consumption, and the process is now near thermodynamic limits. To further reduce energy requirements for desalination, other approaches are needed. A microbial desalination cell (MDC) is a recent technology that could be used as an alternative to RO. An MDC uses electrical current, produced by electrochemically active bacteria, to concurrently generate bioenergy, treat wastewater, and desalinate water. In an attempt to answer the question of whether this emerging technology has the ability to stand alone as an efficient replacement for RO, or it is best if used as an RO pre-treatment setup, this review addresses the recent approaches and limitations of both MDC and RO technologies in order to highlight the near-future application of MDC integration with RO operation.

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