J.R. DeShazo, left, and Gaurav Sant show off a sample of the new building material they have created to replace concrete.
Credit: Roberto Gudino/UCL
Imagine
a world with little or no concrete. Would that even be possible? After all,
concrete is everywhere -- on our roads, our driveways, in our homes, bridges
and buildings. For the past 200 years, it's been the very foundation of much of
our planet.
But
the production of cement, which when mixed with water forms the binding agent
in concrete, is also one of the biggest contributors to greenhouse gas
emissions. In fact, about 5 percent of the planet's greenhouse gas emissions
comes from concrete.
An
even larger source of carbon dioxide emissions is flue gas emitted from
smokestacks at power plants around the world. Carbon emissions from those
plants are the largest source of harmful global greenhouse gas in the world.
A
team of interdisciplinary researchers at UCLA has been working on a unique
solution that may help eliminate these sources of greenhouse gases. Their plan
would be to create a closed-loop process: capturing carbon from power plant
smokestacks and using it to create a new building material -- CO2NCRETE -- that
would be fabricated using 3D printers. That's "up-cycling."
"What
this technology does is take something that we have viewed as a nuisance --
carbon dioxide that's emitted from smokestacks -- and turn it into something
valuable," said J.R. DeShazo, professor of public policy at the UCLA
Luskin School of Public Affairs and director of the UCLA Luskin Center for
Innovation.
"I
decided to get involved in this project because it could be a game-changer for
climate policy," DeShazo said. "This technology tackles global
climate change, which is one of the biggest challenges that society faces now
and will face over the next century."
DeShazo
has provided the public policy and economic guidance for this research. The
scientific contributions have been led by Gaurav Sant, associate professor and
Henry Samueli Fellow in Civil and Environmental Engineering; Richard Kaner,
distinguished professor in chemistry and biochemistry, and materials science
and engineering; Laurent Pilon, professor in mechanical and aerospace
engineering and bio-engineering; and Matthieu Bauchy, assistant professor in
civil and environmental engineering.
This
isn't the first attempt to capture carbon emissions from power plants. It's
been done before, but the challenge has been what to do with the carbon dioxide
once it's captured.
"We
hope to not only capture more gas," DeShazo said, "but we're going to
take that gas and, instead of storing it, which is the current approach, we're
going to try to use it to create a new kind of building material that will
replace cement."
"The
approach we are trying to propose is you look at carbon dioxide as a resource
-- a resource you can re-utilize," Sant said. "While cement production
results in carbon dioxide, just as the production of coal or the production of
natural gas does, if we can re-utilize CO2 to make a building material which
would be a new kind of cement, that's an opportunity."
The
researchers are excited about the possibility of reducing greenhouse gas in the
U.S., especially in regions where coal-fired power plants are abundant.
"But even more so is the promise to reduce the emissions in China and
India," DeShazo said. "China is currently the largest greenhouse gas
producer in the world, and India will soon be number two, surpassing us."
Thus
far, the new construction material has been produced only at a lab scale, using
3-D printers to shape it into tiny cones. "We have proof of concept that
we can do this," DeShazo said. "But we need to begin the process of
increasing the volume of material and then think about how to pilot it
commercially. It's one thing to prove these technologies in the laboratory.
It's another to take them out into the field and see how they work under
real-world conditions."
"We
can demonstrate a process where we take lime and combine it with carbon dioxide
to produce a cement-like material," Sant said. "The big challenge we
foresee with this is we're not just trying to develop a building material.
We're trying to develop a process solution, an integrated technology which goes
right from CO2 to a finished product.
"3-D
printing has been done for some time in the biomedical world," Sant said,
"but when you do it in a biomedical setting, you're interested in
resolution. You're interested in precision. In construction, all of these
things are important but not at the same scale. There is a scale challenge, because
rather than print something that's 5 centimeters long, we want to be able to
print a beam that's 5 meters long. The size scalability is a really important
part."
Another
challenge is convincing stakeholders that a cosmic shift like the researchers
are proposing is beneficial -- not just for the planet, but for them, too.
"This
technology could change the economic incentives associated with these power
plants in their operations and turn the smokestack flue gas into a resource
countries can use, to build up their cities, extend their road systems,"
DeShazo said. "It takes what was a problem and turns it into a benefit in
products and services that are going to be very much needed and valued in
places like India and China."
DeShazo
cited the interdisciplinary team of researchers as a reason for the success of
the project. "What UCLA offers is a brilliant set of engineers, material
scientists and economists who have been working on pieces of this problem for
10, 20, 30 years," he said. "And we're able to bring that team
together to focus on each stage."
According
to Sant, UCLA is the perfect place to tackle sustainability challenges.
"As
one of the leading universities in the world, we see ourselves as having a
blue-sky approach," Sant said. "We see ourselves wanting to develop
technologies that might be considered fanciful at one point but become reality
very quickly. So we see ourselves looking at a blue sky and saying, well then,
let's come up with ideas which will change the world."
https://www.sciencedaily.com
No comments:
Post a Comment