November 8, 2022
Using the Ocean to Fight Climate Change Raises Serious Environmental Justice and Technical Questions
contributor:The Conversation
Heat waves, droughts and extreme weather areendangering people and ecosystemssomewhere in the world almost every day. These extremes are exacerbated by climate change, driven primarily by increasing emissions of greenhouse gases that build up in the atmosphere and trap heat at the Earth’s surface.
With that in mind, researchers areexploring waysto pull carbon dioxide out of the atmosphere and lock it away –including using the ocean.But while these techniques might work, they raise serious technical, social and ethical questions, many of which have no clear answers yet.
We study climate changepolicy, sustainabilityandenvironmental justice.Before people start experimenting with the health of the ocean, there are several key questions to consider.
Humans could sink more carbon in the ocean to fight climate change, but should we? Photo: Arne Hoel / World Bank (CC BY-NC-ND 2.0)
Ocean carbon dioxide removal 101
The ocean covers about 70% of the planet, and itnaturally takes up carbon dioxide.In fact,about a quarterof human-produced carbon dioxide ends up in the ocean.
Ocean carbon dioxide removal is any action designed to use the ocean to remove even more carbon dioxide from the atmosphere than it already does and store it.
It spans a wide range of techniques – from increasing the amount and vitality of carbon dioxide-absorbingmangrove foreststo usingocean fertilizationto stimulate the growth of phytoplankton that absorb carbon dioxide to building pipelines that pumpliquid carbon dioxide into formations under the seabed, where it can eventually solidify as carbonate rock.
There are other forms of carbon dioxide removal – planting trees, for example. But theyrequire large amounts of landthat is needed for other essential uses, such as agriculture.
这就是为什么interest in using the vast ocean is growing.
Methods of ocean direct carbon removal. Image: Rita Erven/GEOMAR viaBoettcher, Brent, Buck, Low, McLaren and Mengis, Frontiers, 2021(CC BY 4.0)
Would these methods store enough carbon?
第一个关键问题是海洋碳dioxide removal techniques could significantly reduce atmospheric carbon dioxide and store it long term, beyond what the ocean already does. Greenhouse gasemissions are still increasing globally, which means that ocean carbon dioxide removal would need to keep carbon dioxide out of the atmosphere for a long time, at least until greenhouse gas emissions have fallen.
Initial evidence suggests that some forms of ocean carbon dioxide removal, such as those that rely on short-lived biomass like kelp forests or phytoplankton,may not keep captured carbon storedfor more than a few decades. That’s because most plant tissues are quickly recycled by decay or by sea creatures grazing on them.
In contrast, mechanisms that form minerals, like the interaction when carbon dioxide is pumped into basalt formations, or that alter the way seawater retains carbon dioxide, such asincreasing its alkalinity,防止碳泄漏和更likely to keep it out of the atmosphere for hundreds or thousands of years.
Ecological risks and benefits
Another key question is what ecological benefits or risks accompany different ocean carbon dioxide removal approaches.
Research shows that some options, such as supporting mangrove forests,may promote biodiversity and benefit nearby human communities.
However, other options could introduce novel risks. For example, growing and then sinking large amounts of kelp or algaecould bring in invasive species.Dissolving certain types of rock in the ocean could reduce ocean acidity. This would enhance the ocean’s ability to store carbon dioxide, but these rocks could also contain trace amounts of metals that could harm marine life, and these risks arenot well understood.
Each process could also release some greenhouse gases, reducing its overall effectiveness.
Phytoplankton can grow explosively over a few days or weeks. This pair of satellite images shows a bloom that formed east of New Zealand between October 11 and October 25, 2009. Ocean fertilization is designed to supercharge that process to capture carbon dioxide, but it can have harmful affects for other marine life. Photo: Robert Simmon and Jesse Allen/NOAA/NASA based on MODIS data
Interfering with nature is a social question
The ocean affects everyone on the planet, but not everyone will have the same relationship to it or the same opportunities to have their opinions heard.
Much of the global population lives near the ocean, and some interventionsmight impinge on places that support jobs and communities.For example, boosting algae growth could affect nearby wild fisheries or interfere with recreation. People and communities are going to evaluate these risks differently depending on how they are personally affected.
In addition, people’s trust in decision-makers oftenshapes their views of technologies.某些方面使用海洋碳移除uch as those close to the shore, could be governed locally. It’s less clear how decisions about thehigh seas or deep oceanwould be made, since these areas are not under the jurisdiction of any one country or global governing body.
People’s perceptions will likely also be shaped by such factors as whether or not they see ocean carbon dioxide removal asinterfering with nature or protecting it.However, views of what is acceptable or not can change. As the impacts of climate change increase,tolerance for some unconventional interventions seems to be growing.
It’s also an ethical question
Ocean carbon dioxide removal also raises a variety of ethical questions that do not have straightforward answers.
For example, it forces people to consider therelationship between humans and nonhumans.Are humans obliged to intervene to reduce the impact on the climate, or ought we avoid ocean interventions? Do people have the right to purposefully intervene in the ocean or not? Are there specific obligations that humans ought to recognize when considering such options?
Other ethical questions revolve around who makes decisions about ocean carbon dioxide removal and the consequences. For example,who should be involved in decision-makingabout the ocean? Could relying on ocean carbon dioxide removalreduce societies’ commitmentto reducing emissions through other means, such as by reducing consumption, increasing efficiency and transforming energy systems?
A woman plants mangroves in Timor Leste. Photo: Yuichi Ishida/UNDP Timor-Leste (CC BY-NC 2.0)
Who pays?
Finally, ocean carbon dioxide removal could be very expensive.
For example, mining and then adding rocks to reduce the ocean’s acidity has beenestimated to costbetween US$60 and $200 per ton of carbon dioxide removed. To put that into context, the world producedmore than 36 billion metric tonsof carbon dioxide from energy alone in 2021.
Even macroalgae cultivation could be in thetens of billions of dollarsif done at the scale likely necessary to have an impact.
These methods are more expensive than many actions that reduce emissions right now. For instance, using solar panels to avoid carbon emissions can range from saving money to a cost of $50 per ton of carbon dioxide, while actions like reducing methane emissions areeven less expensive.But the harm from continued climate change has been estimated to be in thehundreds of billions annuallyin the United States alone.
These costs raise more questions. For example, how much debt is fair for future generations to carry, and how should the costs be distributed globally to fix a global problem?
Ocean carbon dioxide removalcould become a useful methodfor keeping global warming in check, but it should not be seen as a silver bullet, especially since there isn’t an effective global system for making decisions about the ocean.
About the Authors
Sonja Klinsky is an Associate Professor and Senior Global Futures Scientist at Arizona State University.
Terre Satterfield is a Professor of Culture, Risk and the Environment at the University of British Columbia.
Sarah Cooley, a former research scientist at Woods Hole Oceanographic Institution and director of climate science at the Ocean Conservancy, contributed to this article.
This article is republished fromThe Conversationunder a Creative Commons license. Read theoriginal.
