By Robert Sanders, Media relations | JUNE
8, 2018
Last October, a UC Berkeley
team headed down to the Arizona desert, plopped their newest prototype water
harvester into the backyard of a tract home and started sucking water out of
the air without any power other than sunlight.
The successful field test of
their larger, next-generation harvester proved what the team had predicted
earlier in 2017: that the water harvester can extract drinkable water every
day/night cycle at very low humidity and at low cost, making it ideal for
people living in arid, water-starved areas of the world.
“There is nothing like this,”
said Omar Yaghi, who invented the technology underlying the harvester. “It
operates at ambient temperature with ambient sunlight, and with no additional
energy input you can collect water in the desert. This laboratory-to-desert
journey allowed us to really turn water harvesting from an interesting
phenomenon into a science.”
Yaghi, the James and Neeltje
Tretter chair in chemistry at UC Berkeley and a faculty scientist at Lawrence
Berkeley National Laboratory, and his team will report the results of the first
field test of a water-collecting harvester in the June 8 issue of the
journal Science Advances.
The trial in Scottsdale, where
the relative humidity drops from a high of 40 percent at night to as low as 8
percent during the day, demonstrated that the harvester should be easy to scale
up by simply adding more of the water absorber, a highly porous material called
a metal-organic framework, or MOF. The researchers anticipate that with the
current MOF (MOF-801), made from the expensive metal zirconium, they will
ultimately be able to harvest about 200 milliliters (about 7 ounces) of water
per kilogram (2.2 pounds) of MOF, or 3 ounces of water per pound.
But Yaghi also reports that he
has created a new MOF based on aluminum, called MOF-303, that is at least 150
times cheaper and captures twice as much water in lab tests. This will enable a
new generation of harvesters producing more than 400 ml (3 cups) of water per
day from a kilogram of MOF, the equivalent of half a 12-ounce soda can per
pound per day.
“There has been tremendous
interest in commercializing this, and there are several startups already
engaged in developing a commercial water-harvesting device,” Yaghi said. “The
aluminum MOF is making this practical for water production, because it is
cheap.”
Yaghi is also working with
King Abdul Aziz City for Science and Technology in Riyadh, Saudi Arabia, and
its president, Prince Dr. Turki Saud Mohammad Al Saud, on the technology as
part of their joint research Center of Excellence for Nanomaterials and Clean
Energy.
Super-absorbent MOFs
Yaghi is a pioneer in
metal-organic frameworks, which are solids with so many internal channels and
holes that a sugar-cube-size MOF might have an internal surface area the size
of six football fields. This surface area easily absorbs gases or liquids but,
just as important, quickly releases them when heated. Various types of MOFs are
already being tested as a way to pack more gas into the tanks of
hydrogen-fueled vehicles, absorb carbon dioxide from smokestacks and store
methane.
Several years ago, Yaghi
created MOF-801, which absorbs and releases water easily, and last year
he tested
small quantities in a simple harvester to see if he could capture
water from ambient air overnight and use the heat of the sun to drive it out
again for use. That harvester, built by a collaborator at MIT using less than 2
grams of MOF, proved that the concept worked: the windows fogged up in the sun,
though the researchers were not able to collect or accurately measure the
water.
That same harvester was
transported to the desert earlier this year and worked similarly,
though again only droplets of water were generated as a proof of concept.
For the new paper, the UC
Berkeley team — graduate student Eugene Kapustin and postdoctoral fellows
Markus Kalmutzki and Farhad Fathieh — collected and measured the water and
tested the latest generation harvester under varying conditions of humidity,
temperature and solar intensity.
The harvester is essentially a
box within a box. The inner box holds a 2-square-foot bed of MOF grains open to
the air to absorb moisture. This is encased in a two-foot plastic cube with transparent
top and sides. The top was left open at night to let air flow in and contact
the MOF, but was replaced during the day so the box could heat up like a
greenhouse to drive water back out of the MOF. The released water condensed on
the inside of the outer box and fell to the bottom, where the researchers
collected it with a pipette.
The extensive field tests lay
out a blueprint allowing engineers to configure the harvester for the differing
conditions in Arizona, the Mediterranean or anywhere else, given a specific
MOF.
“The key development here is
that it operates at low humidity, because that is what it is in arid regions of
the world,” Yaghi said. In these conditions, the harvester collects water even
at sub-zero dew points.
Yaghi is eagerly awaiting the
next field test, which will test the aluminum-based MOF and is planned for
Death Valley in late summer, where temperatures reach 110 degrees Fahrenheit in
the daytime and remain in the 70s at night, with nighttime humidity as low as
25 percent.
Other co-authors of the paper
are graduate students Peter Waller and Jingjing Yang. The work was supported by
the U.S. National Science Foundation, German Research Foundation and KACST.
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