An almost limitless supply of fresh water exists in the form of water vapor above Earth's oceans, yet remains untapped, researchers said. A new study suggests an investment in new infrastructure capable of harvesting oceanic water vapor as a solution to limited supplies of fresh water in various locations around the world.
From: University of Illinois at Urbana-Champaign,
News Bureau
December 6, 2022 -- The study, led
by civil and environmental engineering professor and Prairie Research Institute
executive director Praveen Kumar, evaluated 14 water-stressed locations across
the globe for the feasibility of a hypothetical structure capable of capturing
water vapor from above the ocean and condensing it into fresh water -- and do
so in a manner that will remain feasible in the face of continued climate
change.
Kumar, graduate student
Afeefa Rahman and atmospheric sciences professor Francina Dominguez published
their findings in the journal Nature Scientific Reports.
"Water scarcity is
a global problem and hits close to home here in the U.S. regarding the sinking
water levels in the Colorado River basin, which affects the whole Western
U.S.," Kumar said. "However, in subtropical regions, like the Western
U.S., nearby oceans are continuously evaporating water because there is enough
solar radiation due to the very little cloud coverage throughout the
year."
Previous wastewater
recycling, cloud seeding and desalination techniques have met only limited
success, the researchers said. Though deployed in some areas across the globe,
desalination plants face sustainability issues because of the brine and heavy
metal-laden wastewater produced -- so much so that California has recently
rejected measures to add new desalination plants.
"Eventually, we
will need to find a way to increase the supply of fresh water as conservation
and recycled water from existing sources, albeit essential, will not be
sufficient to meet human needs. We think our newly proposed method can do that
at large scales," Kumar said.
The researchers
performed atmospheric and economic analyses of the placement of hypothetical
offshore structures 210 meters in width and 100 meters in height.
Through their analyses,
the researchers concluded that capturing moisture over ocean surfaces is
feasible for many water-stressed regions worldwide. The estimated water yield
of the proposed structures could provide fresh water for large population
centers in the subtropics.
One of the more robust
projections of climate change is that dry regions will get drier, and wet areas
will get wetter. "The current regions experiencing water scarcity will
likely be even drier in the future, exacerbating the problem," Dominguez
said. "And unfortunately, people continue moving to water-limited areas,
like the Southwestern U.S."
However, this
projection of increasingly arid conditions favors the new ocean
vapor-harvesting technology.
"The climate
projections show that the oceanic vapor flux will only increase over time,
providing even more fresh water supply," Rahman said. "So, the idea
we are proposing will be feasible under climate change. This provides a much
needed and effective approach for adaptation to climate change, particularly to
vulnerable populations living in arid and semi-arid regions of the world."
The researchers said
one of the more elegant features of this proposed solution is that it works
like the natural water cycle.
"The difference is
that we can guide where the evaporated water from the ocean goes,"
Dominguez said. "When Praveen approached me with this idea, we both
wondered why nobody had thought about it before because it seemed like such an
obvious solution. But it hasn't been done before, and I think it is because
researchers are so focused on land-based solutions -- but our study shows other
options do, in fact, exist."
The researchers said
this study opens the door for novel infrastructure investments that can
effectively address the increasing global scarcity of fresh water.
The University of
Illinois Urbana-Champaign, the Lovell Professorship in the department of civil
and environmental engineering, The University Scholar Program and the National
Science Foundation supported this research.
https://www.sciencedaily.com/releases/2022/12/221206083115.htm
No comments:
Post a Comment