posted on 2022-03-17, 14:22authored byGowri Mohandass, Weikun Chen, Sitaraman Krishnan, Taeyoung Kim
Electrochemical
separation offers an energy-efficient means to
desalinate brackish water, a relatively untapped but increasingly
utilized water source for freshwater supply. Several electrochemical
techniques are being developed to enable low-energy desalination combined
with energy storage. We report a new approach that produced a peak
power density of 6.0 mW cm–2 from the energy stored
in iron cyanide (Fe-CN) and iron citrate (Fe-Cit) redox couples during
water desalination, using asymmetric redox flow batteries (RFBs).
Desalination and the charging of the redox couples occurred in a four-channel
RFB cell. The stored energy was extracted in a two-channel RFB cell.
Desalination of model brackish water (2.9 g L–1)
to freshwater (0.5 g L–1) was also studied in a
symmetric system using the environmentally benign Fe-Cit. The process
was characterized by low energy consumption (0.56 kW h m–3), high productivity (41.1 L freshwater m–2 area
h–1, representing practical operating conditions
for brackish water desalination), and high water recovery (91% product-to-intake
water ratio, addressing the environmental and economic challenges
of brine disposal). The low cell voltage (<0.5 V) required in the
reported system is ideally suited for developing modular desalination
systems powered by renewables, including solar energy. Collectively,
water-based RFBs for desalination and power production would lead
to sustainable water-energy infrastructure.