Marine CO₂ removal technologies could depend on the appetite of the ocean’s tiniest animals

As the world struggles to decarbonise, it’s becoming increasingly clear we’ll need to both rapidly reduce emissions and actively remove carbon dioxide (CO₂) from the atmosphere. The latest Intergovernmental Panel on Climate Change considered 230 pathways to keep global warming below 1.5°C. All required CO₂ removal.

Some of the most promising CO₂ removal technologies receiving government funding in the , and seek to increase the massive carbon storage potential of the ocean. These include and .

Ocean-based are gaining popularity because they could potentially store carbon for of “”, where CO₂ is sucked from the air with energy-intensive machinery.

But the marine carbon cycle is much harder . Scientists must unravel the many complex natural processes that could alter the efficiency, efficacy and safety of ocean-based CO₂ removal before it can go ahead.

In , we highlight a surprisingly important mechanism that had previously been overlooked. If CO₂ removal techniques change the appetite of tiny animals at the base of the food chain, that could dramatically change how much carbon is actually stored.

Plankton dominate the carbon pump

Tiny marine life forms called play a huge role in ocean carbon cycling. These microscopic organisms drift on the ocean currents, moving captured carbon throughout the seas.

Like plants on land, phytoplankton use sunlight and CO₂ to grow through photosynthesis.

, on the other hand, are tiny animals that mostly eat phytoplankton. They come in many . If you put them in a lineup, you might think they came from different planets.

Across all this diversity, zooplankton have very different .
The hungrier they are, they faster they eat.

Uneaten phytoplankton – and zooplankton poo – can sink to great depths, keeping carbon locked away from the atmosphere for centuries. Some even sink to the seafloor, eventually transforming .

This transfer of carbon from the atmosphere to the ocean is known as the “biological pump”. It keeps hundreds of billions of tonnes of carbon . That translates to about CO₂ and of cooling!A variety of zooplankton, tiny marine animals of different shapes and sizes, against a black backgroundA lineup of zooplankton: tiny marine animals that look like they come from different planets.  Julian Uribe-Palomino/IMOS-CSIRO

Picky eaters

In our we wanted to better understand how zooplankton appetites influence the biological pump.

we had to work out how zooplankton appetites differ across the ocean.

We used a to simulate the seasonal cycle of phytoplankton population growth. This is based on the balance of reproduction and death. The model simulates reproduction really well.

Zooplankton appetites . But the model’s not so good at , because it doesn’t have enough information about zooplankton appetites.

So we tested dozens of different appetites and then checked our results against real-world data.

To get global observations of phytoplankton seasonal cycles without a fleet of ships, we used satellite data. This is possible even though phytoplankton are tiny, because their light-catching pigments are .

We ran the model in more than 30,000 locations and found zooplankton appetites vary enormously. That means all those different types of zooplankton are not spread evenly across the ocean. They appear to gather around their favourite types of prey.

, we show how this diversity influences the biological pump.

We compared two models, one with just two types of zooplankton and another with an unlimited number of zooplankton – each with different appetites, all individually tuned to their unique environment.

We found including realistic zooplankton diversity reduced the strength of the biological pump by a billion tonnes of carbon every year. That’s bad for humanity, because most of the carbon that doesn’t go into the ocean ends up back in the atmosphere.

Not all of the carbon in the bodies of the phytoplankton would have sunk deep enough to from the atmosphere. But even if only a quarter did, once that could match annual emissions from the entire .An infographic illustrating the ocean carbon cycle, including phytoplankton photosynthesis and zooplankton grazingIn the ocean carbon cycle, the biological pump begins with the capture of atmospheric carbon dioxide during photosynthesis by phytoplankton. If the phytoplankton die, the carbon in their bodies is stored deep in the ocean. However, zooplankton grazing will release carbon dioxide back into the atmosphere.

The ocean as a sponge

Many ocean-based CO₂ removal technologies will alter the composition and abundance of phytoplankton.

Biological ocean-based CO₂ removal technologies such as “” seek to increase phytoplankton growth. It’s a bit like spreading fertiliser in your garden, but on a much bigger scale – with a fleet of ships seeding iron across the ocean.

The goal is to remove CO₂ from the atmosphere and pump it into the deep ocean. However, because , feeding them iron could change the composition of the population.

Alternatively, non-biological ocean-based CO₂ removal technologies such as “” shift the chemical balance, allowing more CO₂ to dissolve in the water before it reaches chemical equilibrium. However, the most accessible sources of alkalinity are minerals including nutrients that encourage the growth of certain .

If these changes to phytoplankton favour different types of zooplankton with different sized appetites, they are likely to change the strength of the biological pump. This could compromise – or complement – the efficiency of ocean-based CO₂ removal technologies.

The Insanely Important World of Phytoplankton (NASA Goddard)

Moving forward from a sea of uncertainty

Emerging private-sector CO₂ removal companies will require accreditation from reliable . This means they must demonstrate their technology can:

  1. remove carbon for hundreds of years (permanence)
  2. avoid major environmental impacts (safety)
  3. be amenable to accurate monitoring (verification).

Cast against a , the time is now for oceanographers to .

Our research shows CO₂ removal technologies that change phytoplankton communities could also drive changes in carbon storage, by modifying zooplankton appetites. We need to better understand this before we can accurately predict how well these technologies will work and how we must monitor them.

This will require tremendous effort to overcome the challenges of , and zooplankton dynamics. But the payoff is huge. A more reliable regulatory framework could pave the way for a , morally imperative, emerging CO₂ removal industry.

This article is republished from under a Creative Commons license:

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  • Authors: , Lecturer in Southern Ocean Biogeochemical Modelling, IMAS, University of Tasmania; , Professor, University of Cambridge, and , PhD Candidate, University of Cambridge
  • Cover image: Copepod by Julian Uribe-Palomino CSIRO-IMOS

Published 17 June 2024

Authorised by the Executive Director, Institute for Marine and Antarctic Studies
17 June, 2024