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Controversial geoengineering scheme will dump iron in the sea

A former UK chief scientist is planning experiments to drop iron filings in oceans to tackle climate change and restore marine life, in a major geoengineering project that is likely to prove controversial
Phytoplankton bloom in the North Atlantic Ocean
Stocktrek Images, Inc./Alamy

A former UK chief scientific adviser is planning experiments to drop sand naturally containing iron in oceans to tackle climate change and restore marine life, in a major geoengineering project that is likely to prove controversial.

Ships will be sent to three locations across the world’s oceans in the next four years to trial the technique – known as ocean iron fertilisation – David King at the at Cambridge (CCRC), UK, tells èƵ.

The plan is to emulate and accelerate natural processes, such as the way wind transports dust from the Sahara desert and deposits iron in the Atlantic Ocean. The iron fertilises the growth of phytoplankton, which absorbs CO2 from the air, eventually locking it away in the ocean.

King, a former UK chief scientific adviser who earlier this month, says the technique can also help “restock the oceans with fish and animals” – including ultimately helping whale populations – because of the phytoplankton bloom. “It has the greatest promise and the least amount of effort being put into [it] at the moment” of all CO2 removal approaches, says King.

Studies have shown that iron fertilisation can work, but past real-world trials have proven controversial and been accused of violating international rules. King describes his planned experiments, coordinated by the CCRC, as a “big international effort” to explore the approach.

“If the programme works, it’s quite possible with just this one technique that we could be taking up 10 to 30 billion tonnes of greenhouse gases a year,” says King. “We’d have to be covering 2 to 3 per cent of the world’s deep ocean surface with small particles containing iron in order to achieve that. And we are keen to see if we can do that. It’ll be very cheap because iron is very cheap.”

Wil Burns at American University in Washington DC says the scheme may have to clear international governance hurdles to go ahead. A global agreement known as the , which covers the dumping of waste and other materials at sea, would be relevant, he says. It allows for small-scale and research-focused projects, but it is unclear whether this latest plan would be approved.

The scheme may also have to engage with criteria set by the United Nations Convention on Biological Diversity and the UN Convention on the Law of the Sea, says Burns.

Whether further experiments on ocean iron fertilisation are needed has also been called into question by other researchers. by Rob Bellamy at the University of Manchester in the UK and his colleagues, published in February, concluded that “we might reasonably question whether further research is necessary in order to rule this out as an option”.

The technology isn’t at a credible stage, says Bellamy. “There have been quite a few experiments already, but huge uncertainties remain over how much CO2 is captured, and how long it stays down at the bottom of the ocean. The latest best estimates put its potential at a measly 1 to 3 billion tonnes of CO2 removed per annum.” Burns also thinks that King’s CO2 removal estimates are too high, calling them “pie in the sky”.

One of the main stumbling blocks could be public attitudes, as , says Bellamy. “People don’t like it.”

Ocean iron fertilisation is ranked even lower than putting aerosols in the atmosphere to manage the amount of the sun’s energy reaching Earth, he says. Such solar radiation management experiments have received strong pushback, with one effort that was due to go ahead in Sweden being recently postponed for a year.

King says he is aware of the sensitivities around putting iron in the oceans to fight climate change. “That’s why we are stressing that this is a question of returning the oceans to their biological state and, by the way, we take greenhouse gases out of the atmosphere. If the experiments work, which will take at least 4 years, we’ve got to do a very detailed analysis to show no negative impact.” The team have already begun research on public attitudes, he says.

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Article amended on 29 June 2021

We clarified the form of the iron involved

Topics: Climate change / Oceans