THE SNAPSHOT
researchers are helping to answer one of climate action’s most urgent questions: whether the ocean can safely remove carbon dioxide from the atmosphere at meaningful scale. Their work is positioning Nova Scotia as a global leader in carbon-dioxide removal while supporting the growth of a new climate-technology sector for the province.
THE CHALLENGE: Evidence for the environment
Climate action has long focused on cutting the carbon rising from smokestacks, tailpipes and power plants. That remains the essential task. But a second challenge is coming into sharper view: what to do with the carbon already added to the atmosphere, and whether the ocean can help pull some of it back.
Nova Scotia coastal waters are home to leading mCDR research.
The ocean already does this work, absorbing and storing vast amounts of carbon as part of the planet’s natural systems. Proponents of marine carbon dioxide removal believe that capacity can be expanded. But promise is not proof. Before the field can scale, scientists, regulators and communities need evidence that these approaches work, can be measured and pursued safely.
The effort to answer those questions is increasingly drawing the world to Nova Scotia. From April 28 to 30, close to 300 researchers, innovators and policymakers will gather in Halifax for the Annual Convening focused on the science, governance and future of ocean-based carbon dioxide removal.
Canadian of Nova Scotia says Halifax is a strong choice for the gathering, citing its emergence as an international hub where ocean science, climate innovation and a fast-growing marine technology sector are converging. The central question they've come to address is whether the ocean can be leveraged to remove carbon at the pace the climate crisis demands without damaging its fragile ecosystems.
Senator Deacon, whose Senate committee produced a , sees both urgency and risk with the potential for the technology to be stymied by a lack of balance between scientific evidence, regulation, and applied innovation.
Senator Conlin Deacon.
“Social licence is critical to the effective and economically viable effort to scale this technology,” he says of a field whose future will depend on public trust and participation. “If we don’t keep communities informed with the evidence as we scale the technology, then we’re going to face roadblocks everywhere we look.”
That, Senator Deacon says, is where and its (OFI) have become central to the story, helping build the scientific foundation for a field that is drawing attention from around the world.
THE SOLUTION: Ready for climate action
“We’ve got expertise built up in many of the sectors that are required to make good decisions about marine carbon dioxide removal,” says ocean scientist Dr. Erin Bertrand, acting scientific director and CEO of OFI. “We were ready well before the research problem came to the forefront.”
Dr. Bertrand at ’s Steele Ocean Science Building.
At and through OFI’s extended network, dozens of researchers are studying how carbon moves through coastal waters, how removal can be measured and verified, how marine ecosystems may respond, and what safeguards are needed before the nascent industry scales.
Part of that work is supported through , a research program led by OFI built around an ocean-first approach to understanding and mitigating climate change. Backed by $154 million from the Government of Canada through the Canada First Research Excellence Fund, the program includes a dedicated focus on ocean-based carbon dioxide removal.
Learn more about the Transforming Climate Action research program.
For Dr. Bertrand, ’s contribution is rooted in what universities do best — bringing rigor, independence and evidence to questions of consequence. She says, if findings support the field, they can help move it forward. But if not, or not exactly, they can point efforts in new directions.
THE WORK: Putting mCDR to the test
Dr. Bertrand says a concentration of advantages make Nova Scotia unusually well suited to the study of mCDR, anchored by the Bedford Basin. ’s depth in ocean science, a growing marine innovation sector and years of study in this deep, sheltered inlet housing Halifax Harbour form what she calls a “place-based research platform.”
“The Bedford Basin gives us a real advantage,” she says. “We have this long-term time series, and people who are deeply familiar with its oceanographic, biological, and chemical conditions. That baseline allows us to look for the kinds of changes we need to understand if we’re going to properly assess environmental effects.”
Members of Ocean Alk-align team work with Planetary to study their work.
One of the researchers working in Basin is oceanographer Dr. Katja Fennel, the lead principal investigator of , an international project funded by the Carbon to Sea Initiative to study ocean alkalinity enhancement, or OAE, as a promising mCDR method. OAE works by adding alkaline minerals to seawater, increasing its ability to absorb and hold carbon dioxide. The method aims to accelerate the natural process of rock erosion — as rocks weather, they release alkaline minerals that help the ocean store carbon as stable dissolved compounds.
Dr. Fennel and her team are working closely with Halifax-based company to study their OAE operations in the city’s harbour. The company adds alkalinity to the cooling water that exits from Nova Scotia Power’s Tufts Cove Generating Station, allowing researchers to conduct experiments as the outflow mixes into the basin.
Their applied studies allow the researchers to focus on the field’s central challenges: how to best measure, report and verify whether carbon removal is happening, how long it lasts, and whether the ocean and its ecosystems are responding safely.
Researchers retrieve their sensing instrument from the Bedford Basin.
Farther north along Nova Scotia’s eastern coast, the Strait of Canso — the narrow tidal channel separating Cape Breton from the mainland — is set to become another site for ’s growing work in mCDR.
engineer Dr. Adam Yang is working with pHathom, a Halifax-based company developing a different approach to ocean carbon removal. Rather than adding alkalinity directly to seawater, pHathom’s system captures carbon dioxide on land using limestone inside engineered reactors. The process produces bicarbonate-rich material that can be returned to the ocean, where the carbon can be stored.
Dr. Yang preparing for a laboratory tank flow measurement using a dyed liquid.
“The company has developed reactor technology to draw down the CO2. is providing the capacity to test the technology and guidelines for pilot deployments,” says Dr. Yang.
This testing is taking place in the university’s Aquatron, a controlled marine research facility where scientists can simulate ocean conditions before moving experiments into open water. There, Dr. Yang and Dr. Ricardo Arruda, a PhD graduate and OFI/Mitacs-supported postdoctoral fellow working with pHathom, are studying how the bicarbonate-rich material behaves when it enters a marine system like the Strait of Canso.
’s Aquatron, Canada’s largest university-based ocean research facility.
At the same time, another OFI/Mitacs-supported postdoctoral fellow, Dr. Marzia Khosravi, is modelling circulation in the strait, where future field trials will take place. The goal is to understand where the water moves, how it mixes and whether the carbon remains stored over time.
“We want to understand whether circulation will carry the material toward the open ocean,” says Dr. Yang. “Before a pilot study happens, we need to understand whether that is the case.”
THE IMPACT: From Nova Scotia waters to the world
If ’s work helps answer if mCDR can be done safely, credibly and at scale, the impact could reach well beyond the Bedford Basin or the Strait of Canso. It could help secure Nova Scotia’s position as a place where climate technologies are imagined, tested and brought to life with the evidence needed to earn public trust.
“I envision Halifax and Nova Scotia becoming even more of a hub for these approaches,” says Dr. Bertrand. “If we become known as the place where good academic partnered research happens in this space, and we have platforms ready to go to apply to new approaches, we will continue to attract companies and new ideas.”
Senator Deacon centre in the blue coat visits to Planetary OAE site in Halifax.
Senator Colin Deacon sees the same opportunity in broader economic terms. For him, the promise is not simply that mCDR could be tested in Nova Scotia, but that the province could help build the companies and technologies needed to scale it globally.
“I can’t even begin to imagine what the industry will bring here over time. But I can see those with scalable technologies, like Planetary building equipment in Nova Scotia and shipping it to sites anywhere you could imagine,” he says. “This is an opportunity for us to scale a technology globally, because we’re all fighting climate change, and we all have to reduce and remove.”