The ocean is one of our greatest assets in the fight against climate change.
Taking up 70 percent of the earth’s surface,
it produces over 50 percent of the
oxygen we breathe, sustains an
abundance of biodiversity and is the world's largest carbon sink, absorbing
approximately 30-50 percent of the
CO2
produced from burning fossil fuels.
The ocean’s efficiency in absorbing CO2 is also its downfall; the more CO2 it
absorbs, the more acidic it becomes. Ocean acidification is essentially a change
in the chemistry/pH of the ocean, which consequently is leading to “collapsing
food webs, corrosive polar seas, dying coral reefs and mass
extinctions.”
Ocean acidification has increased 25 percent since preindustrial
times
due to human activity and the effects are being seen on a global scale.
Additionally, the processes responsible for ocean carbon removal take millions
of years; and with carbon dioxide becoming ever more prevalent in our
atmosphere, it would be beneficial to find a way to enhance ocean carbon
removal, without the associated impacts of acidification.
Matt Eisaman, Ebb
Carbon's Chief Technology Officer and co-founder,
has spent the last decade researching the ocean carbonate system and how it,
along with electrochemistry, can help the ocean absorb more atmospheric carbon
dioxide. In February 2021, Eisaman and co-founder Ben
Tarbell launched Ebb Carbon —
a company that uses technology and electrochemistry to speed up the ocean's
processes of carbon removal, with the co-benefit of reducing ocean acidity.
“The chemistry of the ocean is well understood, so I always knew that Ebb’s
technology was possible. To date, we have demonstrated that our electrochemical
system is energy-efficient, low-cost, and compatible with the ocean,” Eisaman
told Sustainable Brands™. “So, the question we face today isn’t really
‘can we do this?’ It’s ‘Can we do this fast enough, at a large enough scale to
draw down gigatons of carbon dioxide per year by mid-century?’”
Ebb Carbon’s solution has the potential to be one of the largest-scale and
lowest-cost paths to removing excess carbon from the air. The electrochemical
process works by intercepting the saltwater that saltwater-treating facilities
deposit back into the ocean and adjusting the electricity of its molecules — the
salt and water molecules in saltwater are rearranged to produce acid and
slightly alkaline saltwater solutions. When this alkaline saltwater returns to
the ocean, a natural chemical reaction occurs — and CO2 is pulled out of the air
and stored as bicarbonate.
Image credit: Ebb Carbon
“We are enhancing a carbon-storage process that is already happening. The ocean
has a natural solution for carbon storage: bicarbonate — the ocean’s most
abundant form of carbon storage. It safely stores carbon dioxide for 10,000+
years; and it doesn’t add to the ocean’s acidification problem — it actually
helps solve it,” Eisaman explains.
Ebb Carbon’s system provides a permanent solution to safely store excess carbon
for 10,000+ years. And the process is scalable: Ebb Carbon’s approach uses the
ocean’s vast surface area to capture and store carbon, and its technology is
built with modular, prefabricated elements that easily scale. Ebb’s systems are
designed to be integrated with existing facilities, so can be installed quickly
— drawing down carbon dioxide faster. In addition to carbon removal and
permanent storage, the technology is helping to heal the ocean by reducing its
acidity.
“The reason we have chosen to focus on the ocean is that we believe it is our
best natural ally in relation to climate change — it covers more than 70 percent
of the globe and acts like a sponge that continuously absorbs carbon from the
atmosphere. Because we are harnessing such a vast natural resource, Ebb’s
technology has the potential to have an enormous impact on climate change,”
Eisaman says.
Carbon-removal
technology
is essential in the fight against climate change — according to the most recent
IPCC
report,
5-10 gigatons of CO2 will need to be removed from the air every year between now
and 2050 to prevent the world from overheating. Currently, there are 19 carbon
removal
facilities
worldwide drawing down CO2 from the air. Combined, they capture around 10,000
tons of CO2/year — this is a start, but just a small fraction of what we need.
“The world is going to need a variety of
technologies
to meet the challenge of removing gigatons of carbon from our atmosphere.
Harnessing the power of the ocean in this fight is an underexplored area of
carbon removal; and we’re pleased to be one of the few working on this potential
solution,” Eisaman explains. “We expect Ebb’s ocean-based carbon removal, direct
air capture and other technologies to play an important role in drawing down the
gigatons of carbon we need to remove from our atmosphere.”
Over the next five years, Ebb Carbon is planning to partner with facilities that
process seawater — including desalination plants, aquaculture
facilities
and wastewater treatment
plants.
“Locating our systems alongside facilities that already treat seawater means we
can tap into existing networks of pumps and pipes that process and carry
seawater,” Eisaman explains. “This reduces complexity and cost, and will help us
deploy our systems and remove carbon dioxide from the atmosphere more quickly.”
The first Ebb System will be deployed later this year to deliver carbon
offsets
to its first customer, Stripe. This system will be
rated at one hundred tons of CO2 per year capacity. Over the next few years, Ebb
is set to deploy dozens of similar units which will enable the team to
continually improve the efficiency and cost of the system. By 2027, Ebb plans to
be operating at the megaton scale by partnering with a variety of facilities
that already process seawater.
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Scarlett Buckley is a London-based freelance sustainability writer with an MSc in Creative Arts & Mental Health.
Published Aug 25, 2022 2pm EDT / 11am PDT / 7pm BST / 8pm CEST