This new ‘battery’ aims to spark a carbon capture revolution
<https://www.pbs.org/newshour/science/this-new-battery-aims-to-spark-a-carbo…>
Science <https://www.pbs.org/newshour/science> Nov 15, 2019 2:31 PM EST
Renewable energy alone is not enough to turn the tide of the climate
crisis. Despite the rapid expansion
<https://www.eia.gov/todayinenergy/detail.php?id=38752> of wind, solar and
other clean energy technologies, human behavior and consumption are
flooding our skies with too much carbon, and simply supplanting fossil
fuels won’t stop global warming. To make some realistic attempt at
preventing a grim future
<https://www.rff.org/publications/reports/global-energy-outlook-2019/>,
humans need to be able to physically remove carbon from the air.
That’s why carbon capture technology is slowly being integrated into energy
and industrial facilities across the globe. Typically set up to collect
carbon from an exhaust stream, this technology sops up greenhouse gases
before they spread into Earth’s airways. But those industrial practices
work because these factories produce gas pollutants like carbon dioxide and
methane at high concentrations. Carbon capture can’t draw CO2 from regular
open air, where the concentration of this prominent pollutant is too
diffuse.
Moreover, the energy sector’s transition toward decarbonization is moving
too slowly. It will take years — likely decades
<https://www.pbs.org/newshour/science/how-your-brain-stops-you-from-taking-c…>
—
before the world’s hundreds of CO2-emitting industrial plants adopt capture
technology. Humans have pumped about 2,000 gigatonnes
<https://www.carbonbrief.org/analysis-why-the-ipcc-1-5c-report-expanded-the-…>
—
billions of metric tons — of carbon dioxide into the air since
industrialization, and there will be more.
But what if you could have a personal-sized carbon capture machine on your
car, commercial airplane or solar-powered home?
Chemical engineers at the Massachusetts Institute of Technology have
created a new device that can remove carbon dioxide from the air at any
concentration. Published in October in the journal Energy & Environmental
Science, the project is the latest bid to directly capture CO2 emissions
and keep them from accelerating and worsening future climate disasters.
Think of the invention as a quasi-battery, in terms of its shape, its
construction and how it works to collect carbon dioxide. You pump
electricity into the battery, and while the device stores this charge, a
chemical reaction occurs that absorbs CO2 from the surrounding atmosphere —
a process known as direct air capture. The CO2 can be extracted by
discharging the battery, releasing the gas, so the CO2 then can be pumped
into the ground. The researchers describe this back-and-forth as
electroswing adsorption.
[image: A cross-section of an electroswing adsorber, which is essentially
an electrochemical cell -- that is, a battery. The battery has two active
(negative) electrodes on the outside and a positive (counter) electrode in
the middle (red). When electricity runs into the battery, the active
layers, which are covered with quinone, collect CO2 from the surrounding
air. Image by Sahag Voskian]
A cross-section of an electroswing adsorber, which is essentially an
electrochemical cell — that is, a battery. The battery has two active
(negative) electrodes on the outside and a positive (counter) electrode in
the middle (red). When electricity runs into the battery, the active
layers, which are covered with quinone, collect CO2 from the surrounding
air. Image by Sahag Voskian
“I realized there was a gap in the spectrum of solutions,” said Sahag
Voskian, who co-led the project with fellow MIT chemical engineer T. Alan
Hatton. “Many current systems, for instance, are very bulky and can only be
used for large-scale power plants or industrial applications.”
Relative to current technology, this electroswing adsorber could be
retrofitted onto smaller, mobile sources of emissions like autos and
planes, the study states. Voskian also pictures the battery being scaled to
plug into power plants powered by renewables, such as wind farms and solar
fields, which are known to create more energy than they can store. Rather
than lose this power, these renewable plants could set up a side hustle
where their excess energy is used to capture carbon.
“That’s one of the nice aspects of this technology — is that direct linkage
with renewables,” said Jennifer Wilcox, a chemical engineer at Worcester
Polytechnic Institute, who was not involved in the study.
Imagine turning the more than 2 million U.S. homes with rooftop solar into
mini-carbon capture plants.
The advantage of an electricity-based system for carbon capture is that it
scales linearly. If you need 10 times more capacity, you simply build 10
times more of these “electroswing batteries” and stack them, Voskian said.
He estimates that if you cover a football field with these devices in
stacks that are tens of feet high, they could remove about 200,000 to
400,000 metric tons of CO2 a year. Build another 100,000 of these fields,
and they could bring carbon dioxide in the atmosphere back to preindustrial
levels within 40 years.
One hundred thousand installations sounds like a lot, but keep in mind that
these devices can be built to any size and run off the excess electricity
created by renewables like wind and solar, which at the moment cannot be
easily stored
<https://www.pbs.org/newshour/science/can-germany-revive-its-stalled-transit…>.
Imagine turning the more than 2 million U.S. homes with rooftop solar
<https://www.seia.org/news/united-states-surpasses-2-million-solar-installat…>into
mini-carbon capture plants.
On paper, this invention sounds like a game changer. But it has a number of
feasibility hurdles to surmount before it leaves the laboratory.
How this electroswing battery works
The idea of using electricity to trigger a chemical reaction —
electrochemistry — as a means for capturing carbon dioxide isn’t new. It
has been around for nearly 25 years, in fact
<https://www.sciencedirect.com/science/article/pii/0196890495001487>.
But Voskian and Hatton have now added two special materials into the
equation: quinone and carbon nanotubes.
A carbon nanotube is a human-made atom-sized cylinder — a sheet of carbon
molecules spread into a single layer and wrapped up like a tube. Aside from
being more than 100 times stronger
<https://www.nature.com/articles/s41467-019-10959-7> than stainless steel
or titanium, carbon nanotubes are excellent conductors of electricity,
making them sturdy building blocks for electrified equipment.
Much like a regular battery, Voskian and Hatton’s device has a positive
electrode and a negative electrode — “plus” and “minus” sides. But the
minus side — the negative electrode — is infused with quinone, a chemical
that, after being electrically charged, reacts and sticks to CO2.
When you charge the battery, you have carbon capture. When you discharge
it, you release the carbon that you captured.
“You can think of it like the charge and discharge of a battery,” Voskian
said. “When you charge the battery, you have carbon capture. When you
discharge it, you release the carbon that you captured.”
Their approach is unique because all the energy required for their direct
air capture comes from electricity. The three major startups in this
emerging space — Climeworks <https://www.climeworks.com/>, Global Thermostat
<https://globalthermostat.com/>and Carbon Engineering
<https://carbonengineering.com/> — rely on a mixture of electric and
thermal (heat) energy, Wilcox said, with thermal energy being the dominant
factor.
For power plants and industrial facilities, that excess heat — or waste
heat, a byproduct of their everyday work, isn’t a perfect fit for carbon
capture. Waste heat isn’t very consistent. Imagine standing next to a fire
— its warmth changes as the flames flit about.
[image: The electroswing adsorbers can be stacked, so air can flow between
them. Image by Sahag Voskian]
The electroswing adsorbers can be stacked, so air can flow between them.
Image by Sahag Voskian
This heat can come from carbon-friendly options — such as a hydrothermal
plant — but some current startups are preparing their capture systems to
run on thermal energy from fossil-fuel burning facilities
<https://globalthermostat.com/the-gt-solution/>. So they may capture 1.5
tons of CO2, but they also generate about half a ton in the process
In Voskian’s operation, “We don’t have any of that. We have full control
over the energetics of our process,” he said.
Will it work?
Voskian and Hatton, who have launched a startup called Verdox, write in
their study that operating electroswing carbon capture would cost between
$50 to $100 per metric ton of CO2.
“If it’s true, that’s a great breakthrough,” said Richard Newell, president
and CEO of Resources for the Future, a nonprofit research organization that
develops energy and environmental policy on carbon capture
<https://www.rff.org/publications/reports/global-energy-outlook-2019/>.
But, he cautioned, “the distance between showing something in the
laboratory and then demonstrating it at a commercial scale is very big.”
If it’s true, that’s a great breakthrough.
— Richard Newell, president and CEO of Resources for the Future
The costs for capturing carbon and storing it (or sequestration) typically
fall into three bins: the price of physically capturing the gas, the price
of transporting the CO2 to a disposal site and the price of burying it in
the ground.
Direct air capture is the most expensive form of sequestration because CO2
concentrations in the atmosphere are so low. “Recent estimates for direct
air capture are in the range of $125 to $325 per ton,” Newell said.
It is cheaper to collect carbon in an industrial setting where the
pollution is high. The most optimal locations are natural gas production
sites, ethanol plants and ammonia factories, where the costs range from $20
to $30 per metric ton of CO2, Newell said. Head to a power plant or cement
maker — where the facilities are bigger — and costs are $50 to $100 per
metric ton.
All of this means the costs of Voskian and Hatton’s device would be on par
with the cheapest options for carbon sequestration in general, not just
among the market for direct air capture.
[image: Air, including carbon dioxide (red), flows in between the stacks of
electroswing adsorbers. Below: Once electrified (white), the quinone
attracts carbon dioxide out of the air. Image by Sahag Voskian]
Air, including carbon dioxide (red), flows in between the stacks of
electroswing adsorbers. Below: Once electrified (white), the quinone
attracts carbon dioxide out of the air. Image by Sahag Voskian
This price point for electroswing seems sensible but a little surprising,
Wilcox said, given carbon nanotubes are two to 10 times more expensive than the
base materials for other forms of direct air carbon capture
<https://www.nap.edu/download/25259>.
She also worries that carbon capture technology for large industrial
operations has reached a stage of development where it might be difficult
to catch up to and outcompete them. She co-authored a report earlier this
year with the National Academy of Sciences that predicts the price of
direct air carbon capture will drop over time, but reach a competitive
price point of $100 per metric ton of CO2 until the second half of the
century, after significant deployment.
“Scale up will take time and learning by doing should help in cost
reductions,” Wilcox said, adding that current direct air startups are also
solidifying their positions in the market. “Climeworks is at a commercial
scale. Global Thermostat and Carbon Engineering are just about there.”
Scale up will take time.
— Jennifer Wilcox, chemical engineer, Worcester Polytechnic Institute
Moreover, she questions the ease at which electroswing scrubbers could be
adapted for transportation, contrasting the situation with catalytic
converters used by cars to prevent nitrogen oxides (NOx) pollution. An
automobile’s catalytic converter reduces NOx emissions by turning the
pollutant into non-harmful nitrogen and water vapor.
That strategy won’t work for CO2, given the end goal is burying it. If your
car is burning fuel and capturing carbon from the tailpipe, the CO2 would
need to be stored in a tank, which would quickly weigh down the vehicle.
What would one do with compressed tanks of CO2?
“You’d have to establish a secondary market for taking CO2 tanks off
people’s cars,” Wilcox said, which would be difficult given there isn’t
much commercial demand for carbon dioxide.
All that said, Wilcox and Newell believe electroswing tech is an
interesting new arena for carbon capture. Given nearly 40 billion metric
tons of CO2 are still added to the atmosphere each year, any feasible
solution for climate mediation deserves deployment, they said.
“We can’t meet our goals by just avoiding CO2. It’s not going to work
anymore,” Wilcox said. “We need all hands on deck.”
Left: Smoke and steam billows from Belchatow Power Station, Europe's
largest coal-fired power plant near Belchatow, Poland on November 28, 2018.
Inventors claim a new carbon capture “battery” could be retrofitted for
industrial plants but also for mobile sources of CO2 emissions like cars
and airplanes. Photo by REUTERS/Kacper Pempel
Related
- Jane Fonda: ‘Older women have always tended to be the bravest’
<https://www.pbs.org/newshour/arts/jane-fonda-older-women-have-always-tended…>
By Joshua Barajas
- Only 2 countries are meeting their climate pledges. Here’s how the 10
worst could improve
<https://www.pbs.org/newshour/science/only-2-countries-are-meeting-their-cli…>
By Nsikan Akpan
- How more organic farming could worsen global warming
<https://www.pbs.org/newshour/science/how-more-organic-farming-could-worsen-…>
By Courtney Vinopal
- The hotter the planet grows, the less children are learning
<https://www.pbs.org/newshour/science/kids-learn-less-on-hot-days-global-war…>
By Nsikan Akpan
Go Deeper
- carbon emissions <https://www.pbs.org/newshour/tag/carbon-emissions>
- chemistry <https://www.pbs.org/newshour/tag/chemistry>
- climate change <https://www.pbs.org/newshour/tag/climate-change>
- global warming <https://www.pbs.org/newshour/tag/global-warming>
- innovation and invention <https://www.pbs.org/newshour/tag/invention>
- massachusetts institute of technology
<https://www.pbs.org/newshour/tag/massachusetts-institute-of-technology>
[image: Nsikan Akpan] <https://www.pbs.org/newshour/author/nsikan-akpan>
By —
Nsikan Akpan <https://www.pbs.org/newshour/author/nsikan-akpan>
Nsikan Akpan is the digital science producer for PBS NewsHour and
co-creator of the award-winning, NewsHour digital series ScienceScope
<https://www.pbs.org/newshour/tag/sciencescope>. For secure communication,
he can be reached via Signal (240) 516-8357.
------------------------------
<https://twitter.com/MoNscience>
William V. DePaulo, Esq.
860 Court Street North, Suite 300
Lewisburg, WV 24901
Tel 304-342-5588
Fax 866-850-1501
william.depaulo(a)gmail.com