MIT Reseachers Develop New Way
to Clear Pollutants from Water
Electrochemical method can remove
even tiny amounts of contamination
David L. Chandler | MIT News Office
May 10, 2017 -- When it comes to removing very dilute concentrations of pollutants from water, existing separation methods tend to be energy- and chemical-intensive. Now, a new method developed at MIT could provide a selective alternative for removing even extremely low levels of unwanted compounds.
to Clear Pollutants from Water
Electrochemical method can remove
even tiny amounts of contamination
David L. Chandler | MIT News Office
May 10, 2017 -- When it comes to removing very dilute concentrations of pollutants from water, existing separation methods tend to be energy- and chemical-intensive. Now, a new method developed at MIT could provide a selective alternative for removing even extremely low levels of unwanted compounds.
The new approach is described in
the journal Energy and Environmental Science, in a paper by MIT
postdoc Xiao Su, Ralph Landau Professor of Chemical Engineering T. Alan Hatton,
and five others at MIT and at the Technical University of Darmstadt in Germany
The system uses a novel method,
relying on an electrochemical process to selectively remove organic
contaminants such as pesticides, chemical waste products, and pharmaceuticals,
even when these are present in small yet dangerous concentrations. The approach
also addresses key limitations of conventional electrochemical separation
methods, such as acidity fluctuations and losses in performance that can happen
as a result of competing surface reactions.
Current systems for dealing with
such dilute contaminants include membrane filtration, which is expensive and
has limited effectiveness at low concentrations, and electrodialysis and
capacitive deionization, which often require high voltages that tend to produce
side reactions, Su says. These processes also are hampered by excess background
salts.
In the new system, the water flows
between chemically treated, or “functionalized,” surfaces that serve as
positive and negative electrodes. These electrode surfaces are coated with what
are known as Faradaic materials, which can undergo reactions to become
positively or negatively charged. These active groups can be tuned to bind
strongly with a specific type of pollutant molecule, as the team demonstrated
using ibuprofen and various pesticides. The researchers found that this process
can effectively remove such molecules even at parts-per-million concentrations.
Previous studies have usually
focused on conductive electrodes, or functionalized plates on just one
electrode, but these often reach high voltages that produce contaminating
compounds. By using appropriately functionalized electrodes on both the
positive and negative sides, in an asymmetric configuration, the researchers
almost completely eliminated these side reactions. Also, these asymmetric
systems allow for simultaneous selective removal of both positive and negative
toxic ions at the same time, as the team demonstrated with the herbicides
paraquat and quinchlorac.
The same selective process should
also be applied to the recovery of high-value compounds in a chemical or
pharmaceutical production plant, where they might otherwise be wasted, Su says.
“The system could be used for environmental remediation, for toxic organic
chemical removal, or in a chemical plant to recover value-added products, as
they would all rely on the same principle to pull out the minority ion from a
complex multi-ion system.”
The system is inherently highly
selective, but in practice it would likely be designed with multiple stages to
deal with a variety of compounds in sequence, depending on the exact
application, Su says. “Such systems might ultimately be useful,” he sugggests,
“for water purification systems for remote areas in the developing world, where
pollution from pesticides, dyes, and other chemicals are often an issue in the
water supply. The highly efficient, electrically operated system could run on
power from solar panels in rural areas for example.”
Unlike membrane-based systems that
require high pressures, and other electrochemical systems that operate at high
voltages, the new system works at relatively benign low voltages and pressures,
Hatton says. And, he points out, in contrast to conventional ion exchange
systems where release of the captured compounds and regeneration of the
adsorbents would require the addition of chemicals, “in our case you can just flip
a switch” to achieve the same result by switching the polarity of the
electrodes.
The research team has already
racked up a series of honors for the ongoing development of water treatment
technology, including grants from the J-WAFS Solutions and Massachusetts Clean
Energy Catalyst competitions, and the researchers were the top winners last
year’s MIT Water Innovation Prize. The researchers have applied for a patent on
the new process. “We definitely want to implement this in the real world,”
Hatton says. In the meantime, they are working on scaling up their prototype
devices in the lab and improving the chemical robustness.
This technique “is highly
significant, as it extends the capabilities of electrochemical systems from
basically nonselective toward highly selective removal of key pollutants,” says
Matthew Suss, an assistant professor of mechanical engineering at Technion
Institute of Technology in Israel
These researchers “have
systematically explored a variety of device configurations and a variety of
contaminants,” says Kyle Smith, a professor of mechanical science and
engineering at the University
of Illinois
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